Determining a temperature value by analyzing audio

ABSTRACT

In general, the subject matter described in this disclosure can be embodied in methods, systems, and computer-readable devices. An audio processing device plays a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece. The audio processing device records, while playing the source audio signal, a recorded audio signal using the electroacoustic transducer. The audio processing device identifies one or more parameters that indicate how properties of the user earpiece affect playing of the source audio signal, at least one of the parameters being temperature dependent. The audio processing device determines a temperature value estimated to cause the source audio signal that was played by the audio processing device to result in the recorded audio signal, accounting for changes to the source audio signal that occur due to the one or more parameters.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation in Part of U.S. application Ser. No. 16/419,979, filed May 22, 2019, which is a Continuation of U.S. application Ser. No. 16/119,691, filed Aug. 31, 2018, now U.S. Pat. No. 10,334,350, which is a continuation of U.S. application Ser. No. 15/606,374, filed May 26, 2017, now U.S. Pat. No. 10,097,914, which claims the benefit of U.S. Application Ser. No. 62/379,160, filed Aug. 24, 2016, U.S. Application Ser. No. 62/342,872, filed May 27, 2016, U.S. Application Ser. No. 62/342,871, filed May 27, 2016, and U.S. Application Ser. No. 62/342,869, filed May 27, 2016 the contents of which applications are incorporated herein by reference in their entirety. This application is a Continuation in Part of U.S. application Ser. No. 16/778,232, filed Jan. 31, 2020, which is a Continuation of U.S. application Ser. No. 16/119,769, filed Aug. 31, 2018, now U.S. Pat. No. 10,555,102, which is a Continuation of U.S. application Ser. No. 15/312,591 filed Nov. 18, 2016, now U.S. Pat. No. 9,973,870, which is a National Stage Application under 35 U.S.C. § 111(a) of International Application No. PCT/IL2015/050525, filed May 18, 2015, which claims the benefit of U.S. Provisional Application 62/000,626, filed May 20, 2014. The disclosure of the foregoing applications are hereby incorporated by reference in their entirety.

BACKGROUND

The present invention, in some embodiments thereof, relates to measurements using earphone output speakers and, more specifically, but not exclusively, to temperature, biometric and/or acoustic measurements from an electro-acoustic output transducer of an earphone.

Physiological and environmental measurements may be performed by dedicated devices or by adding special sensors to accessory devices of client terminals. For example, glass analog and/or electronic digital thermometers are used for body temperature measurements. The device may be designed to measure body temperature from skin contact, or through the ear canal using infrared heat emission sensors. For example, special temperature sensors have been added to earphones for measuring temperature on a Smartphone while listening to music or participating in a voice call.

Personal use pulse rate monitors use pulse sensors and dedicated electronics to measure pulse rate when needed, or continually during exercise. The dedicated pulse rate sensors may be incorporated into chest bands, wrist bands, and earphones.

During voice conversations on cellular and/or cordless phones, a microphone is used to measure the voice signal of a participant in the call, and the signal is sent in real time to the other participant. An additional microphone may be used to reduce the background and/or Gaussian noise from the voice signal.

Earphones for mobile devices contain dedicated electro-acoustic output transducers, also referred to as earphone output speakers, to play music and/or voice signals from remote participants.

With the proliferation of mobile computing devices in recent years, users have turned increasingly to earbuds, headphones, and other types of headsets to listen to an increasing supply of audio content made available through these mobile computing devices. Smartphones, for instance, typically include a headphone jack that allows users to connect headsets to the phone, through which a user may listen to songs from a media library or streaming service, podcasts, audio tracks from videos, and a variety of other content sources of the user's preference. Users may also use headsets that include earbuds and an external microphone placed near the user's mouth to hold telephone calls for a hands-free mobile call experience. While listening to audio through a headset of a mobile device (or other computing device), the user may be interrupted by various events that require the user's attention, including ceasing to listen to the audio for a period of time. In some instances, the user may interact with applications or other resources on a device having restricted access. In some instances, the user may attempt to listen to audio content in a noisy environment that makes the audio content difficult for the user to hear.

SUMMARY

According to some embodiments of the present invention there is provided a method of using an earphone output speaker as a microphone for a phone call between two or more participants. The method may comprise playing a received voice signal to one or more electro-acoustic output transducer of one or more earphone, wherein the received voice signal is a voice of a remote participant recorded from a remote client terminal. The method may comprise instructing an audio processing integrated circuit of a local client terminal to record a voice signal from the one or more electro-acoustic output transducer, wherein the voice signal is a voice of a local participant using the local client terminal. The method may comprise calculating a transmission voice signal based on a function combining the recorded voice signal, the received voice signal, and filtration coefficients, using a processing unit of the local client terminal. The method may comprise sending the transmission voice signal through an output interface of the local client terminal, thereby enabling acoustic voice playing of the transmission voice signal on the remote client terminal at a remote location for a phone call communication.

Optionally, the one or more electro-acoustic output transducer is an external speaker connected to an earphone.

Optionally, the one or more electro-acoustic output transducer is an internal speaker of the client terminal.

Optionally, the voice signal recording and the received voice signal playing are performed simultaneously from the same electro-acoustic transducer.

Optionally, the voice signal recording and the received voice signal playing are performed alternately from the same electro-acoustic transducer, where for a first time period playing is performed and for a second time period recording is performed in short enough time to be inaudible.

According to an aspect of some embodiments of the present invention there is provided a computer readable medium comprising computer executable instructions adapted to perform the methods described herein.

According to an aspect of some embodiments of the present invention there is provided a method of sending a noise reduced voice signal to a remote participant of a phone call between two or more participants. The method may comprise playing a received voice signal to one or more electro-acoustic output transducer of one or more earphone, wherein the received voice signal is a voice of a remote participant recorded from a remote client terminal. The method may comprise instructing an internal microphone integral to a local client terminal to record a voice signal, wherein the voice signal is a voice of a local participant using the local client terminal. The method may comprise instructing an audio processing integrated circuit of the local client terminal to record an aural audio signal using the one or more electro-acoustic output transducer. The method may comprise calculating a noise reduced voice signal based on a function combining the voice signal, the aural audio signal, the received voice signal and filtration coefficients, using a processing unit of the local client terminal. The method may comprise sending the noise reduced voice signal through an output interface, thereby enabling acoustic playing of the noise reduced voice signal on the remote client terminal at a remote location for a phone call communication.

Optionally, the aural audio signal recording and received voice signal playing are performed simultaneously from the same electro-acoustic output transducer.

According to an aspect of some embodiments of the present invention there is provided a method of presenting a pulse rate measurement. The method may comprise playing an output audio signal to one or more electro-acoustic output transducer of one or more earphone. The method may comprise instructing an audio processing integrated circuit of a client terminal to record an aural audio signal using the one or more electro-acoustic output transducer. The method may comprise calculating a pulse rate measurement based on a function combining the aural audio signal, the output audio signal, and filtration coefficients. The method may comprise presenting the pulse rate measurement.

Optionally, the aural audio signal recording and the output audio signal playing are performed simultaneously from the same one or more electro-acoustic output transducer.

Optionally, the aural audio signal recording and the output audio signal playing are performed alternately from the same one or more electro-acoustic output transducer, where for a first time period playing is performed and for a second time period recording is performed in short enough to be inaudible.

Optionally, the electro-acoustic transducer is located inside an ear canal during recording of the aural audio signal.

Optionally, the pulse rate measurement is calculated based on measurement of a time shift between the aural audio signal and a second aural audio signal recorded from one or more second electro-acoustic output transducer.

Optionally, the pulse rate measurement is calculated based on a change in frequency response of an ear canal.

Optionally, the pulse rate measurement is presented to a user through a user interface.

Optionally, the pulse rate measurement is presented to a remote device through an output interface.

According to an aspect of some embodiments of the present invention there is provided a method of presenting a temperature measurement. The method may comprise playing an output audio signal to one or more electro-acoustic transducer. The method may comprise instructing an audio processing integrated circuit of a client terminal to record an audio signal using one or more electro-acoustic transducer. The method may comprise calculating two or more temperature measurements based on a function combining the audio signal, an output audio signal and filtration coefficients. The method may comprise presenting one or more of two or more temperature measurements.

Optionally, the one or more electro-acoustic transducer is a microphone.

Optionally, the one or more electro-acoustic transducer is an output speaker of an earphone.

Optionally, the one or more electro-acoustic transducer is an external speaker connected to an earphone, and two or more temperature measurement comprises ambient and inner ear temperature measurements.

Optionally, the one or more electro-acoustic transducer is an internal speaker of a client terminal, and two or more temperature measurement comprises ambient and device temperature measurements.

Optionally, the electro-acoustic transducer is located inside an ear canal of a target user during recording of the audio signal and one of two or more temperature measurements is an inner ear measurement correlated with a body temperature of the target user.

Optionally, one or more of two or more temperature measurement is presented to a user through a user interface.

Optionally, one or more of two or more temperature measurement is presented to a remote device through an output interface.

According to an aspect of some embodiments of the present invention there is provided a computer program product for sending a transmission voice signal. The computer program product may comprise a computer readable storage medium. The computer program product may comprise first program instructions to play a received voice signal to one or more electro-acoustic output transducer of one or more earphone. The computer program product may comprise second program instructions instruct an audio processing integrated circuit of a local client terminal to record a voice signal using the one or more electro-acoustic output transducer. The computer program product may comprise third program instructions to calculate a transmission voice signal based on a function combining the recorded voice signal. The computer program product may comprise fourth program instructions to send the transmission voice signal through an output interface of the local client terminal, and the first, second, third, and fourth program instructions may be stored on the computer readable storage medium.

According to an aspect of some embodiments of the present invention there is provided a computer program product for sending a noise reduced voice signal. The computer program product may comprise a computer readable storage medium. The computer program product may comprise first program instructions to play a received voice signal to one or more electro-acoustic output transducer of one or more earphone. The computer program product may comprise second program instructions instructing an internal microphone integral to a client terminal to record a voice signal. The computer program product may comprise third program instructions to instruct an audio processing integrated circuit of the client terminal to record an aural audio signal using one or more electro-acoustic output transducer. The computer program product may comprise fourth program instructions to calculate a noise reduced voice signal based on a function combining the voice signal, the aural audio signal and filtration coefficients. The computer program product may comprise fifth program instructions to send the noise reduced voice signal through an output interface of the client terminal, and the first, second, third, fourth, and fifth program instructions are stored on the computer readable storage medium.

According to an aspect of some embodiments of the present invention there is provided a computer program product for presenting a pulse rate measurement. The computer program product may comprise a computer readable storage medium. The computer program product may comprise first program instructions to play an output audio signal to one or more electro-acoustic output transducer of one or more earphone. The computer program product may comprise second program instructions instruct an audio processing integrated circuit of a client terminal to record an aural audio signal using one or more electro-acoustic output transducer. The computer program product may comprise third program instructions to calculate a pulse rate measurement based on a function combining the recorded aural audio signal. The computer program product may comprise fourth program instructions to present the pulse rate measurement, and the first, second, third, and fourth program instructions are stored on the computer readable storage medium.

According to an aspect of some embodiments of the present invention there is provided a computer program product for presenting a temperature measurement. The computer program product may comprise a computer readable storage medium. The computer program product may comprise first program instructions to play an output audio signal to one or more electro-acoustic output transducer of one or more earphone. The computer program product may comprise second program instructions instruct an audio processing integrated circuit of a client terminal to record an aural audio signal using one or more electro-acoustic output transducer. The computer program product may comprise third program instructions to calculate a temperature measurement based on a function combining the recorded aural audio signal. The computer program product may comprise fourth program instructions to present the temperature measurement, and the first, second, third, and fourth program instructions are stored on the computer readable storage medium.

According to an aspect of some embodiments of the present invention there is provided a device for sending a voice signal to a remote participant in a phone conversation. The device may comprise an interface for sending a local voice signal of a local participant in the phone conversation and receiving a remote voice signal of a remote participant. The device may comprise an audio socket for connecting an earphone to the device. The device may comprise one or more storage units with sets of processor instructions for performing the action of playing a received voice signal to one or more output speaker of one or more earphone. A storage unit may comprise sets of processor instructions for performing the action of instructing an audio circuit to record an aural signal from the one or more output speaker of the earphone A storage unit may comprise sets of processor instructions for performing the action of computing the local voice signal from the aural signal A storage unit may comprise sets of processor instructions for performing the action of sending the local voice signal to a player device of the remote participant in the phone conversation. The device may comprise one or more processing unit configured for retrieving the sets of processor instructions from the one or more storage unit, and executing the sets of processor instructions.

Optionally, the device comprises a microphone, the microphone records a second voice signal, the voice signal is a noise reduced voice signal computed using the aural signal and the second voice signal.

According to an aspect of some embodiments of the present invention there is provided a device for presenting a biometric measurement. The device may comprise an audio socket for connecting an earphone to the device. The device may comprise one or more storage unit containing sets of processor instructions for playing an output audio signal to one or more output speaker of one or more earphone. A storage unit may contain sets of processor instructions for instructing an audio circuit to record an aural signal from the one or more output speaker of the earphone. A storage unit may contain sets of processor instructions for computing one or more biometric measurement from the aural signal. A storage unit may contain sets of processor instructions for presenting the one or more biometric measurement. The device may comprise one or more processing unit configured for retrieving the sets of processor instructions from the one or more storage unit, and executing the sets of processor instructions.

Optionally, the device comprises a data interface, and the one or more biometric measurement is presented on a remote device using the data interface.

Unless otherwise defined, all technical and/or scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of embodiments of the invention, exemplary methods and/or materials are described below. In case of conflict, the patent specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and are not intended to be necessarily limiting.

Implementation of the method and/or system of embodiments of the invention may involve performing or completing selected tasks manually, automatically, or a combination thereof. Moreover, according to actual instrumentation and equipment of embodiments of the method and/or system of the invention, several selected tasks could be implemented by hardware, by software or by firmware or by a combination thereof using an operating system.

For example, hardware for performing selected tasks according to embodiments of the invention could be implemented as a chip or a circuit. As software, selected tasks according to embodiments of the invention could be implemented as a plurality of software instructions being executed by a computer using any suitable operating system. In an exemplary embodiment of the invention, one or more tasks according to exemplary embodiments of method and/or system as described herein are performed by a data processor, such as a computing platform for executing a plurality of instructions. Optionally, the data processor includes a volatile memory for storing instructions and/or data and/or a non-volatile storage, for example, a magnetic hard-disk and/or removable media, for storing instructions and/or data. Optionally, a network connection is provided as well. A display and/or a user input device such as a keyboard or mouse are optionally provided as well.

This specification generally relates to audio signal processing, including techniques for applying acoustic headsets connected to an audio processing device (e.g., a phone) as a sensor for collecting data that the device can leverage to provide a variety of services to a user. For example, the techniques discussed herein may enable a software platform on a device to utilize off-the-shelf earphones as a powerful, external multi-sensor that can sense characteristics of a user and the user's environment in real-time. Some implementations of the techniques discussed herein include detecting the presence of an earpiece at a user's ear, verifying a person's identity based on acoustic characteristics of a user's ear, performing active noise cancellation using pre-recorded sounds, and calculating temperatures of various environments using a transducer of an earpiece.

The details of one or more implementations are set forth in the accompanying drawings and the description below. Other features, objects, and advantages, will be apparent from the description and drawings, and from the claims.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1A is a schematic illustration of a system and device to calculate an, optionally noise reduced, voice signal from an earphone output speaker, according to some embodiments of the invention.

FIG. 1B is a schematic illustration of a system and device to calculate a pulse and/or temperature measurement from an aural signal recorded from an earphone output speaker, according to some embodiments of the invention.

FIG. 1C is a flowchart of a method to generate a phone conversation audio signal from an earphone output speaker, according to some embodiments of the invention.

FIG. 1D is a flowchart of a method to measure a pulse rate from an earphone output speaker, according to some embodiments of the invention.

FIG. 1E is a flowchart of a method to measure temperature from an earphone output speaker, according to some embodiments of the invention.

FIG. 1F is a schematic illustration of a user interface to record a signal from an earphone output speaker, compute signals and/or measures data, and outputting the data, according to some embodiments of the invention.

FIG. 2A depicts a conceptual diagram of a user listening to a source audio signal played through a smartphone, using a pair of earbuds. As the source audio signal is played, the earbuds simultaneously function as a microphone to capture an aural signal that results within the user's ear as the audio signal is played.

FIG. 2B is a block diagram of an example audio processing device that is configured to carry out various ones of the techniques described herein.

FIG. 2C is a schematic that illustrates a configuration between a coding/decoding component (commonly referred to as a “codec”) and an earpiece for simultaneous playing and recording using a transducer of the earpiece.

FIG. 2D is a schematic that illustrates another configuration between a coding/decoding component and an earpiece for simultaneous playing and recording using a transducer of the earpiece.

FIG. 2E is a schematic that illustrates a configuration between a coding/decoding component and two earpieces for simultaneous playing and recording using transducers of the earpieces.

FIG. 3 is a flowchart of an example process for authenticating a user based on acoustic characteristics of a user's ear. The process involves (i) an enrollment phase in which an acoustic signature is generated for a specific user and registered with the user's account, and (ii) a verification stage in which a user's identity is verified based on comparison of features from an aural signal associated with a user to acoustic signatures that are registered with the user's account.

FIG. 4 is a flowchart of an example process for generating an acoustic signature of a user in the enrollment phase of the authentication procedure.

FIG. 5 is a flowchart of an example process for verifying a user's identity in the verification phase of the authentication procedure.

FIG. 6 is a flowchart of an example process for determining the impulse response of an acoustic echo (w_(a)) of a space in which an earpiece is located, e.g., for generating an acoustic signature of a user, detecting the presence of an earpiece at a user's ear, or authenticating a user.

FIG. 7 is a flowchart of an example process for detecting the presence of an earpiece at a user's ear based on features derived from an aural signal recorded during playing of a source audio signal.

FIG. 8 is a process for using a stored instance of a pre-recorded audio signal to cancel interference resulting from the pre-recorded audio signal playing in an environment of a user as the user listens to a source audio signal through a headset.

FIG. 9A-D show a process for determining the temperature of a user and an environment using a transducer.

FIG. 10 shows another process for determining the temperature of a user and an environment using a transducer.

FIG. 11 depicts an example computer that may be configured to carry out the computer-implemented methods and other techniques described herein. In some examples, an audio processing device may include a combination of hardware and software like that discussed with respect to FIG. 2A.

Like numbers and indicators among the various drawings indicate like elements.

DETAILED DESCRIPTION

The present invention, in some embodiments thereof, relates to measurements using earphone output speakers and, more specifically, but not exclusively, to temperature, biometric and/or acoustic measurements from an electro-acoustic output transducer of an earphone.

Current methods for biometric and aural sound measurements require dedicated hardware and electronics, increasing the product cost, development time and development costs. Additionally, some of these methods may require the user to be stationary during measurements as the measurement devices are sensitive to background noise and subject motion.

To overcome these limitations, one or more output speakers of earphones may be used for making measurements while the user is listening to music, soundtrack, a voice of a phone conversation, and the like using the same output speakers. An audio processing circuit of a client terminal, optionally with a rewiring adaptor, may be configured to record an aural sound signal from the earphone electro-acoustic output transducer, such as an earphone output speaker. For example, the earphones and client terminal are off-the-shelf products, with no special hardware incorporated into the client terminals. The aural sound signal may be processed by the processor of the client terminal to produce measurements of temperature, pulse rate, noise signal, and voice signal. As used herein, the term client terminal means a smartphone, a mobile phone, a portable music player, a tablet, a laptop, a wearable device, a personal computer, and the like. As used herein, the term earphone refers to earphones, headphones, earbuds and the like, comprising at least one output speaker, such as an electro-acoustic transducer. The earphones can be regular earphones used for everyday voice conversations and music playing, and do not require special sensors or hardware.

For example, the aural sound signal can be used to compute a voice signal for use in a phone conversation with a remote participant. In another example, the client terminal and/or earphone have an integrated microphone, and the aural sound signal can be used to compute a noise-reduced voice signal for a phone conversation. In another example, the acoustic characteristics of the aural sound signal are sensitive to the temperature of the inside and outside of the earphone electro-acoustic output transducer. In this example, processing the aural sound signal with dedicated methods allows computing temperature measurements for the inner ear and surroundings. In another example, analyzing the periodic features of one or more aural sound signals allows computing a pulse rate.

For example, using existing thermometer devices require the subject to be relatively stationary and may not be capable of monitoring the temperature for long periods of time during normal daily activities. Using some embodiments of the methods described herein, an earphone output speaker may be used to measure the body temperature conveniently and continuously, enabling application of body temperature monitoring for fertility uses, healthy monitoring, emotional monitoring, and/or other uses. Using an aural sound signal recorded from the output speaker internal to the client terminal allows measuring the temperature of the client terminal and determines the power usage based on the temperature measurement. If the client terminal transceiver, processor and display usage do not account for the power usage, the client terminal may be malfunctioning. The recorded aural sound signal is recorded from the same speakers used for playing music and/or listening to a voice signal during a phone conversation.

According to some embodiments of the present invention there is provided computerized methods and devices, for using earphone output speakers to record aural acoustic signals and convert these signals to measurements of the environment of the earphone output speakers. The client terminal devices may have an audio processing integrated circuit, or as referred to herein as a coder/decoder (CODEC), that may be configured to allow signal recording from the same earphone output speakers used for playing music. As used herein, the term CODEC means an audio processing integrated circuit which may comprise a circuit or integrated circuit used to process the input and output of audio signals of the client terminal. The aural acoustic signal may be processed using the client terminal to compute measurements relating to the output speakers environment. For example, the aural acoustic signal is processed to produce a voice signal of the owner of the mobile client terminal for use in a phone conversation, even when no microphone is connected to the CODEC. For example, the acoustic signal is used to produce a noise reduced voice signal from a voice signal collected from a microphone. For example, the aural acoustic signal is used to compute a heart sound from an earphone output speaker located near and/or internal to the ear canal. For example, the acoustic signal is used to compute a heart rate from an earphone output speaker located near and/or internal to the ear canal. For example, the aural acoustic signal is used to compute a body temperature from an earphone output speaker located near and/or internal to the ear canal. For example, the aural acoustic signal is used to compute an ambient temperature from an earphone output speaker.

Optionally, a rewiring adapter is used to enable the CODEC to record an aural audio signal from the earphone output speakers.

Before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not necessarily limited in its application to the details of construction and the arrangement of the components and/or methods set forth in the following description and/or illustrated in the drawings and/or the Examples. The invention is capable of other embodiments or of being practiced or carried out in various ways.

The present invention may be a system, a method, and/or a computer program product. The computer program product may include a computer readable storage medium (or media) having computer readable program instructions thereon for causing a processor to carry out aspects of the present invention.

The computer readable storage medium can be a tangible device that can retain and store instructions for use by an instruction execution device. The computer readable storage medium may be, for example, but is not limited to, an electronic storage device, a magnetic storage device, an optical storage device, an electromagnetic storage device, a semiconductor storage device, or any suitable combination of the foregoing. A non-exhaustive list of more specific examples of the computer readable storage medium includes the following: a portable computer diskette, a hard disk, a random access memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or Flash memory), a static random access memory (SRAM), a portable compact disc read-only memory (CD-ROM), a digital versatile disk (DVD), a memory stick, a floppy disk, a mechanically encoded device such as punch-cards or raised structures in a groove having instructions recorded thereon, and any suitable combination of the foregoing. A computer readable storage medium, as used herein, is not to be construed as being transitory signals per se, such as radio waves or other freely propagating electromagnetic waves, electromagnetic waves propagating through a waveguide or other transmission media (e.g., light pulses passing through a fiber-optic cable), or electrical signals transmitted through a wire.

Computer readable program instructions described herein can be downloaded to respective computing/processing devices from a computer readable storage medium or to an external computer or external storage device via a network, for example, the Internet, a local area network, a wide area network and/or a wireless network. The network may comprise copper transmission cables, optical transmission fibers, wireless transmission, routers, firewalls, switches, gateway computers and/or edge servers. A network adapter card or network interface in each computing/processing device receives computer readable program instructions from the network and forwards the computer readable program instructions for storage in a computer readable storage medium within the respective computing/processing device.

Computer readable program instructions for carrying out operations of the present invention may be assembler instructions, instruction-set-architecture (ISA) instructions, machine instructions, machine dependent instructions, microcode, firmware instructions, state-setting data, or either source code or object code written in any combination of one or more programming languages, including an object oriented programming language such as Smalltalk, C++ or the like, and conventional procedural programming languages, such as the “C” programming language or similar programming languages. The computer readable program instructions may execute entirely on the user's computer, partly on the user's computer, as a stand-alone software package, partly on the user's computer and partly on a remote computer or entirely on the remote computer or server. In the latter scenario, the remote computer may be connected to the user's computer through any type of network, including a local area network (LAN) or a wide area network (WAN), or the connection may be made to an external computer (for example, through the Internet using an Internet Service Provider). In some embodiments, electronic circuitry including, for example, programmable logic circuitry, field-programmable gate arrays (FPGA), or programmable logic arrays (PLA) may execute the computer readable program instructions by utilizing state information of the computer readable program instructions to personalize the electronic circuitry, in order to perform aspects of the present invention.

Aspects of the present invention are described herein with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the invention. It will be understood that each block of the flowchart illustrations and/or block diagrams, and combinations of blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer readable program instructions.

These computer readable program instructions may be provided to a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions/acts specified in the flowchart and/or block diagram block or blocks. These computer readable program instructions may also be stored in a computer readable storage medium that can direct a computer, a programmable data processing apparatus, and/or other devices to function in a particular manner, such that the computer readable storage medium having instructions stored therein comprises an article of manufacture including instructions which implement aspects of the function/act specified in the flowchart and/or block diagram block or blocks.

The computer readable program instructions may also be loaded onto a computer, other programmable data processing apparatus, or other device to cause a series of operational steps to be performed on the computer, other programmable apparatus or other device to produce a computer implemented process, such that the instructions which execute on the computer, other programmable apparatus, or other device implement the functions/acts specified in the flowchart and/or block diagram block or blocks.

The flowchart and block diagrams in the Figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods, and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of instructions, which comprises one or more executable instructions for implementing the specified logical function(s). In some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems that perform the specified functions or acts or carry out combinations of special purpose hardware and computer instructions.

Reference is now made to FIG. 1A, which is a schematic illustration of a system 100 and device 101 to calculate a voice signal, optionally noise reduced, from an earphone output speaker 160, according to some embodiments of the invention. In some embodiments, a client terminal device 101 may contain a user interface 109, a processing unit 102, an audio circuit 110, a voice and/or data interface 108, and an audio socket 109. The user interface 109 may be used to control the operation of the device, issue command, such as to initiate a phone call, and to see the calculated results of the methods. One or more audio sockets 109 may be used to connect one or more audio plugs 124 of earphones 121 to the client terminal 101.

The processing unit 102 may be configured to retrieve processor instructions from a storage unit 103, controlling the audio circuit 110, and transferring data to or from the interfaces. The storage unit 103 may contain processor instructions for configuring an audio circuit 110, also referred to as an audio processing integrated circuit, to record from an earphone output speaker 113, thus enabling the recording of an aural audio signal from earphone output speakers. For example, the aural signal 160 is recorded from the ear(s) 132 of the local phone conversation participant 130 using an earphone 121 output speaker 122, while an output voice signal of the remote participant 159 is being transmitted to the same ear(s) 132. The storage unit 103 may further contain processor instructions for receiving an output audio signal 114 to be played on the earphone output speaker 159, such as the voice signal from a remote participant 140 in phone conversation. The recording is performed from the same output speakers used to play the remote participant voice signal. The storage unit 103 may further contain processor instructions for recording 115 an aural audio signal 160 from the output earphones. The storage unit 103 may further contain processor instructions for computing a voice signal 118 of the local participant 130 from the aural audio signal 160, such that the voice signal is suitable for sending to a remote participant 140 in a phone conversation. Optional, the storage unit 103 may further contain processor instructions for recording a direct voice signal 115 from a microphone, as at 107. Optionally, the storage unit 103 may further contain processor instructions to calculate a noise reduced voice signal 118 based on the aural voice signal, direct voice signal, and filtration coefficients. Optionally, the storage unit 103 may further contain processor instructions to send the noise reduced voice signal to the remote participant 140 of the phone conversation. Optionally, the microphone is part of the earphone 123, such as a headset. The storage unit 103 may further contain processor instructions for sending a voice signal 116, optionally noise reduced, to a remote client terminal 141.

The device may comprise and a voice and/or data interface 108 for placing a phone conversation with a remote client terminal 141 through a network 150, such as a cellular and/or Ethernet network. The device may be connected to an earphone 121 and the earphone may contain one or more output speakers 122 and one or more optional microphones 123.

Reference is now made to FIG. 1B, which is a schematic illustration of a system 160 and device 101 to calculate a pulse and/or temperature measurement from an aural signal recorded from an earphone output speaker, according to some embodiments of the invention. In some embodiments, a client terminal device 101 may contain a user interface 109, a processing unit 102, a storage unit 103, an audio circuit 110, and an audio socket 109. The user interface 109 may be used to control the operation of the device, issue command, such as to request a pulse and/or temperature measurement, and to see the calculated result. An audio socket 109 may be used to connect one or more audio plugs 124 of earphones 121 to the audio circuit 110 of the client terminal 101.

The storage unit 103 may contain processor instructions for instructing 113 an audio circuit 110, also referred to as an audio processing integrated circuit, to record an aural signal from an earphone 121 output speaker 122. The storage unit 103 may further contain processor instructions for receiving an output audio signal 114 to be played on the earphone 121 output speaker(s) 122, such as a music signal to be played 159 while performing the aural signal recording and calculating biometric measurements. The storage unit 103 may further contain processor instructions for recording 115 an aural signal 160 from the earphone 121 output speaker(s) 122. The storage unit 103 may further contain processor instructions for calculating biometric measurements 117 based on the aural audio signal 160, such as pulse rate and temperature measurements. The storage unit 103 may further contain processor instructions for outputting biometric measurement data 119 to a client terminal 101 user interface 109. Optionally, a data interface 108 may be used to output the biometric measurements to a remote storage and/or display on a network 150, such as in tele-monitoring of biometric data.

Optionally, the client terminal 101 may also contain one or more internal output speakers 106 for measuring the intern temperature of client terminal and/or the ambient temperature of the client terminal surroundings.

Both the system for phone conversations 100 and the system for biometric measurements 160 may comprise a large portion of system components in common. For example, the client terminal 101 and earphones 121 may be the same hardware, applied to different use cases and using different calculations. For example, the client terminal 101 and earphones 121 are both off-the-shelf products with no special hardware technical features.

According to some embodiments of the present invention there are provided computerized methods, for using earphones for noise reduction in voice conversations, and/or to use earphones as a microphone in voice conversations.

Reference is now made to FIG. 1C, which is a method to generate a phone conversation voice signal from an earphone output speaker, according to some embodiments of the invention. The computerized processing unit 102 of a client terminal 101 may instruct an audio processing integrated circuit 110 to record 161 from an earphone 121 output speaker 122. A remote voice signal is received 165 by the local client terminal 101 from a remote client terminal 141 of the remote participant 140 in the phone conversation and played 166 on the earphone output speaker 159. Concurrent with the remote voice signal output on the earphones 121, an aural audio signal is recorded 162 from the local earphone 121 output speaker 122. After receiving filtration coefficients 167, the recorded audio and separately received remote voice signal may be used to calculate the local voice signal 163 by a processing unit 102. This local voice signal is then sent by a processing unit 102 to the remote participant client terminal 164, thus enabling a voice signal without using a microphone connected to the local client terminal device.

When the local client terminal 101 has an attached microphone, the method may be used to send a noise reduced local voice signal to the remote terminal 164 by a processing unit 102. A computerized processing unit 102 instructs an audio processing circuit 110 to record 169 a voice signal of the local participant from the microphone 107, and then records 170 the local participant's voice signal from the microphone 107. The recorded voice signal is used with the filtration coefficients 167, remote voice signal 165, and the recorded audio signal 160 from the local earphone 121 output speaker 122 to calculate 163 a noise reduced local voice signal by a processing unit 102, which is sent 164 by a processing unit 102 to the remote participant client terminal 141.

According to some embodiments of the present invention there are provided computerized methods, for recording heart sounds and/or measuring pulse rate using the same earphones output speakers used for playing audio signals.

Reference is now made to FIG. 1D, which is a flowchart of a method to measure a pulse rate from an earphone 121 output speaker 122, according to some embodiments of the invention. A processing unit 102 instructs the audio circuit 110 to record 171 an audio signal from an earphone output speaker 122, and subsequently records 172 the audio signal from the earphone output speaker. A previously received audio signal 175 may be outputted concurrently 176 on the earphone output speaker 122, as at 159. After receiving filtration parameters 177, the recorded audio and received audio output signal are used by a processing unit 102 to calculate the heart sound signal and/or pulse rate 173. The heart sound signal and/or pulse rate are outputted 174 by a processing unit 102 to a user interface 109 and/or to a remote device through a data interface 108 and the internet 150.

According to some embodiments of the present invention there are provided computerized methods, for measuring temperature using an output audio transducer, such as one or more earphone output speakers.

Reference is now made to FIG. 1E, which is a flowchart of a method to measure temperature from an earphone output speaker 122, according to some embodiments of the invention. A processing unit 102 instructs the audio circuit 110 to record 181 an audio signal from an earphone 121 output speaker 122, and subsequently records 182 the audio signal from the earphone output speaker as at 160. A previously received audio signal 185 may be outputted by a processing unit 102 concurrently, for example simultaneously or interleaved, on the earphone output speaker 186. After receiving filtration parameters 187, the recorded audio and received audio output signal are used by a processing unit 102 to calculate the temperature data of the inner ear, user's body and ambient surroundings of the earphone output speaker 183. The temperature data is then outputted 184 by a processing unit 102 to a user interface 109 and/or to a remote device through a data interface 108 and the internet 150.

According to some embodiments of the present invention there are provided computerized methods, for a client terminal to receive input from a microphone and/or acoustic output transducers of earphones. The methods may be used if the audio processing circuit may be configured to use the earphones as an input source to record the sounds within the ear space either simultaneously or interleaved. The calculated signal may be a voice signal even though there is no microphone connected to the client terminal. For example, the output speakers of earphones are used to record a voice signal for a phone call application.

The recorded signal from the earphones may be used to calculate a voice signal, optionally together with input from the microphone to produce a reduced noise voice signal.

Optionally, a background signal is collected from one or more speaker of the earphones.

Optionally, a voice conversation is enabled in smartphones using only earphones, without a connected microphone. For example, a music player as a client terminal without an internal microphone and/or without an earphone microphone participates in a phone conversation using a WiFi™ data connection using the earphone output speakers as a microphone. In this example, the music player is configured to record the aural signal and compute a voice signal for sending to the remote participant of the phone conversation.

According to some aspects of embodiments of the invention, the method configures an audio circuit to connect an input path from the earphones to the audio processing circuit of the client terminal. The method may allow either alternating or simultaneous recording from one or both output speakers of the earphones. For example, alternating recording may be done during short intervals while the output signal to the speakers is stopped, such that the listener does not hear a break in the speaker acoustic output. For example, simultaneous recording may be done concurrently with an audio output signal being played from the earphone output speakers. For noise reduction applications, the method may allow receiving input from an optional microphone.

For example, reference is now made to an exemplary function for calculating a noise reduction signal. For brevity, the following are defined:

E denotes an input signal vector recorded from output earphone(s) speaker(s);

A denotes an output audio signal vector transmitted to the earphone(s), where A=0 if the recording is interleaved;

M denotes an input signal vector recorded by microphone(s);

Ce[N₁] denotes earphone(s) output coefficients, a vector of N₁ number of elements;

Ve[N₂] denotes earphone(s) translation constants, calibrated per user and earphone(s), a vector of N₂ number of elements;

Cf[N₃] denotes filtration coefficients, a vector of N₃ number of elements; and

T denotes a microphone noise reduction coefficient vector.

When there is no microphone input, a voice signal may be calculated using a function such as Ve*Cf*(E−Ce*A), where * denotes the convolution function.

Optionally, input is collected from two or more earphones and E denotes the average input signal. For example, E₁ is collected from the left earphone and E₂ is collected from the right earphone, and E denotes the average of E₁ and E₂.

Optionally, N₁, N₂ and N₃ have different values. These different values correspond to different frequency response functions of the different filter coefficient vectors.

For example, when an audio output signal A is sent to be played by the earphones, the acoustic audio output of the earphones is C_(e)*A.

For example, when E is the audio signal recorded inside the ear from the earphone output speakers, K=V_(e)*E is the speech signal sound.

For example, filtration coefficients implement a weight function on the frequencies, where a weight of 0 is applied to the low frequencies for which the skull doesn't block outside noise well and applied to frequencies which are outside the speech spectrum. Non-zero weights are applied to frequencies inside the speech spectrum for which the skull blocks outside noise.

When a voice signal is collected from a microphone, the noise reduced voice signal may be calculated using the function T*Cf*M.

The coefficients T may be recalculated for a time period, for example, 0.1 seconds. T may be calculated from the equation: T=argmin_(T)(∥T*M−V _(e) *C _(f)*(E−C _(e) *A)∥²) where argmin is defined as the value of the given argument, Tin this example, for which the function in parentheses attains its minimum value.

This function may find the best noise reduction filter that correlates between the earphone and microphone recordings of a voice signal. Similarly, the two recordings may be used to also find background noises that may be reduced from the microphone recordings. For example, background white noise is reduced from the microphone recording. For example, a repetitive background noise is reduced from the microphone recording, such as a train and/or other motor vehicle noise. For example, a noise reduced voice signal may be calculated using the equation M−V_(e)*C_(f)*(E−C_(e)*A).

Optionally, the cross-correlation is computed between two audio signals to find background sounds, and the background sounds removed from an audio signal that comprises a voice signal, resulting in the voice signal being more audible.

Optionally, a cost function is minimized to find T using mathematical optimization. For example, the minimum of a cost function ∥T*M−V_(e)*C_(f)*(E−C_(e)*A)∥² may be found using iterative methods, heuristic methods, and/or by solving corresponding linear equations. For example, the cost function minimum may be found using a simplex method, a least squares method, a newton-raphson method, a simulated annealing method, a combinatorial algorithm, and the like.

According to some embodiments of the present invention there are provided computerized methods, for a client terminal to measure heart pulse rate using these audio output transducers while these audio output transducers are inside or tightly placed over the user's ear(s). For example, the output transducers may be used instead of microphones to record the acoustic signals from the blood pulse in the ears, and the signal is used to calculate a heart pulse rate.

Optionally, the acoustic recording from the output audio transducer is either simultaneous or interleaved (alternating) with the playing of an audio signal from the same output audio transducer.

Optionally, the acoustic recording is performed from the transducer of one ear, from both ears separately, or from both ears together.

Optionally, three phenomena may be used to estimate the user's pulse rate.

The first phenomenon is that venous pulse may be audible inside the ear. This phenomenon may be used by assuming that the audio recorded inside and/or adjacently to the ear may be modeled by a signal P+N where P is the venous pulse signal and N is noise signal. When the recording is performed while transmitting an audio output signal then N may be the sum of transmitted audio, noise from the sound card, and white noise. When the recording is interleaved then N may only be the sum of noise from the sound card and white noise.

The subscripts 1 and 2 of the signals P₁ and P₂ denote the venous pulse signals in each of two ears. These signals are similar and include a time shift due to the different flow paths from the heart to the arteries of each ear.

The second phenomenon that may be used to calculate pulse rate is that the time shift between P₁ and P₂ may be inversely proportional to the pulse rate. Hence, finding the time shift between P₁ and P₂ may determine pulse rate, since it may have a linear relationship with the time shift under certain conditions for a specific person in a small enough time interval. This linear relationship may be more complicated when the person's parameters, such as age, height, weight, and sex, are not assumed. This linear relationship may be more complicated when the pulse value range varies during the measurement period. Optionally, the non-linear aspects of the relationship between time shift and pulse rate are calibrated specifically for each individual.

The third phenomenon used to measure the pulse rate is that changes in the blood pressure may cause changes in the volume of the ear canal. The blood pressure may be inversely proportional to the volume of ear canal. Thus, calculating the changes in the ear canal volume may be used to deduce the blood pressure wave. Any changes in the volume of the ear canal may change the frequency response of the ear canal. Calculating the ear canal frequency response may be done by simultaneously playing and recording an audio signal from a transducer inside and/or tightly placed over the ear.

For example, reference is now made to exemplary functions for calculating a pulse rate from an audio signal. For example, functions ALG. 1 and ALG. 2 use the first phenomenon while functions ALG. 3 and ALG. 4 use the second phenomenon. When input signals from each of both ears are recorded, functions ALG. 1 and ALG. 3 may be used to find the pulse rate. When input from only one ear is recorded, then function ALG. 1 may be used to find the pulse rate. When the sum of recorded inputs from both ears is known than functions ALG. 2 and ALG. 4 may be used to find the pulse rate. Optionally, a number of functions and/or algorithms are used and the average result outputted. For example, function ALG. 5 uses the third phenomenon to calculate a pulse rate.

Functions for calculating a pulse rate from an audio signal may use a windowed autocorrelation function to find patterns of similarity in the recorded audio signal from the output transducer. These windowed autocorrelation functions may find the repetitive heart beat sound in the recorded audio signal by searching for the repeating patterns of a segment of the audio recording.

For brevity, the following are additionally defined:

Ce[ ] denotes transducer coefficients vector

A[ ] denotes an output audio signal vector transmitted by the transducer

CV_(sc)[ ][ ] denotes a covariance matrix of the sound card noise W denotes a window interval length for pulse rate measurement

D_(r) denotes a number of samples corresponding to 0.1 of one heart beat period

E[ ] denotes an input signal vector from an output transducer

S_(d) denotes a number of samples corresponding to shift between P₁ and P₂ where

d is number of samples per heart beat

${{{R{\lbrack\rbrack}}{\lbrack\rbrack}}\mspace{14mu}{denotes}\mspace{14mu}{an}\mspace{14mu} r \times r\mspace{14mu}{matrix}\mspace{14mu}{such}\mspace{14mu}{that}\mspace{14mu}{CV}_{sc}} = {{RR}^{\prime}T{{C{\lbrack\rbrack}}{\lbrack\rbrack}}\mspace{14mu}{denote}\mspace{14mu}{the}\mspace{14mu} t \times t\mspace{14mu}{matrix}\mspace{14mu}{equal}\mspace{14mu}{to}\mspace{14mu}\begin{pmatrix} R \\ I \\ {- R} \\ {- I} \end{pmatrix}\left( {{R^{\prime}I} - R^{\prime} - I} \right)}$

E₁[ ] and E₂[ ] denote input signal vectors from the individual transducers

E[ ] may denote the sum of signals from both transducers

fr denotes audio signal sample rate in samples per second

hr denotes the heart rate in beats per minute hr=60×fr/(10×D_(r))

Optionally, ALG. 1 finds the pulse rate from an audio signal modeled by E=P_(i)+N_(i), when N_(i) is the sum of transmitted audio, noise from the sound card, and white noise. In this model E may be an audio signal from either of the ears. Only the overall length of the signal matters.

Let F=E−Ce*A, and the operator z[x,y] denotes the subvector of z between indices x and y inclusive. For example, F₁=E₁−Ce*A₁ and F₂=E₂−Ce*A₂. The correlation function in this example is: Y ^(i,j) =F[i·W,(i+1)·W]−F[i·W+j,(i+1)·W+j]

In this example, hr is calculated for hr values between 50 and 150 using the cost function: Σ_(i=1 . . . M)Σ_(j=9Dr,9Dr+1, . . . ,11Dr)Σ_(k=1, . . . ,W−t) Y _(i,j)[k,k+t]^(T) TC ⁻¹ Y _(i,j)[k,k+t]  ALG. 1 where M=length(E)/W, and the output is the value of hr corresponding to the maximal value of the cost function ALG. 1, taking into account the relationship between D_(r) and hr.

For example, sampling rate is 44 KHz, of 44,000 samples per second, signal is measured for 10 seconds, and heart rate is 1 beat per second or 44,000 samples per heart beat (d). So total samples is 10*44,000=440,000. Dr is 4,400, and j may have values from 9*4,400 (39,600) to 11*4,400 (48,400). Given a W equivalent to 3 pulses (=3 seconds) then W=3*44,000=132,000 and i may have values from 1 to 3.

Optionally, ALG. 2 finds the pulse rate from an audio signal modeled by E=P₁+P₂+N, where N denotes the sum of transmitted audio from both ears, noise from the sound card, and white noise.

The correlation function in this case is: Y _(i,j) =F[i·W,(i+1)·W]−F[i·W+j,(i+1)·W+j]

In this example, hr is calculated for hr values between 50 and 150 using the cost function: E _(i=1 . . . M)Σ_(j=9Dr, . . . ,11Dr(Σ) _(k=1, . . . ,W−t) Y _(i,j)[k,k+t]^(T) TC ⁻¹ Y _(i,j)[k,k+t])(Σ_(k=1,W−t) Y _(i,j)[S _(j) +k,S _(j) +k+t]^(Y) TC ⁻¹ Y _(i,j)[S _(j) +k,S _(j) +k+t])  ALG. 2 and the output is the value of hr corresponding to the maximal value of the cost function ALG. 2, taking into account the relationship between D_(r) and hr.

Optionally, ALG. 3 finds the pulse rate from an audio signal modeled by E₁=P₁+N₁ and E₂=P₂+N₂, where N_(i) denotes the sum of transmitted audio, noise from the sound card, and white noise for each ear.

The correlation function in this example is: Z _(i,j) =F ₁[i·W,(i+1)·W]−F ₂[i·W+j,(i+1)·W+j]

In this example, hr is calculated for hr values between 50 and 150 using the cost function: Σ_(i=1 . . . M)Σ_(j=9Dr, . . . ,11Dr)Σ_(k=1, . . . ,W−t) Z _(i,Sj)[k,k+t]^(T) TC ⁻¹ Z _(i,Sj)[k,k+t]  ALG. 3 and the output is the value of hr corresponding to the maximal value of the cost function ALG. 3, taking into account the relationship between D_(r) and hr.

Optionally, ALG. 4 finds the pulse rate from an audio signal modeled by E=P₁+P₂+N, where N denotes the sum of transmitted audio, noise from the sound card, and white noise.

The correlation function in this case is: Y _(i,j) =F[i·W,(i+1)·W]−F[i·W+j,(i+1)·W+j]

In this example, hr is calculated for hr values between 50 and 150 using the cost function: Σ_(i-1 . . . M)Σ_(j=9Dr, . . . ,11Dr)(Σ_(k-1, . . . ,W−t) Y ^(i,j)[S _(j) +k,S _(j) +k+t]^(T) TC ⁻¹ Y _(i,j)[S _(j) +k,S _(j) +k+t])   ALG. 4 and the output is the value of hr corresponding to the maximal value of the cost function ALG. 4, taking into account the relationship between D_(r) and hr.

Optionally, there is no transmitted audio and A[ ]=0.

Optionally, the tolerance for calculated heart rate is modified. For example, the definitions above define D_(r) and example functions for a tolerance of 10%, or D_(r). Alternative definitions and functions may be written for higher or lower tolerance in the calculated heart rate, such as tolerance of 5% in heart beat per minute, 2% in heart beat per minute, 1% in heart beat per minute, 0.1% in heart beat per minute, and the like.

Optionally, the window for computing heart rate, denoted W, has a value corresponding to the number of samples of two or more heart beats. Optionally, the window for computing heart rate has a value corresponding to the number of samples of between 3 and 12 heart beats.

Optionally, the input signal vector is recorded from an output transducer with standard, off-the-shelf earphones without special hardware requirements.

Optionally, the input signal vector is recorded from an output transducer during subject movement and/or in the presence of background noise.

Optionally, the input signal vector is recorded from an output transducer during playing of an output audio signal through the same output transducer.

Optionally, ALG. 5 finds the pulse rate from the blood pressure signal. The blood pressure signal may be calculated by playing an output signal through the transducer placed inside the ear, denoted by A[ ], record the signal through the same and/or another transducer placed inside the ear, denoted by E[ ], and using an algorithm to estimate the blood pressure signal from E[ ] and A[ ]. The algorithm may exploit the phenomenon that E[ ] contains A[ ] echoed by the ear canal. These echoes are influenced by the frequency response of the ear canal volume, which is in correlation with the blood pressure signal.

For brevity, the following are additionally defined:

-   -   E[ ] denotes the audio signal recorded by the transducer;     -   A[ ] denotes the audio signal played by the client terminal;     -   C_(t)[ ] denotes the coefficient vector of frequency response of         the transducer;     -   C_(e)(i)[ ] denotes the coefficient vector of frequency response         of the ear canal at time frame i;     -   T[ ] denotes the function between differences of C_(e)(i)'s and         the volume derivative of the ear canal signal; T[ ] is an output         of a calibration process, executed in advance.     -   D_(i) denotes the derivative of blood pressure signal at time i,         and D_(i)=−<T, C_(e)(i+1)−C_(e)(i)>; and     -   BP denotes the blood pressure signal, and         BP(i)=Σ_(i=1 . . . l)D_(j).

To calculate the blood pressure signal, first divide the signals E[ ] and A[ ] to short consecutive intervals in a length between second/(5*pulse) and second/(50*pulse). Denote the i-th interval by A(i) and E(i). Estimate C_(e)(i) by: C _(e)(i)=argmin ∥E(i)−C _(t) *A(i)+C _(e)(i)*C _(t) *A(i)∥²  ALG. 5 and calculate: D _(i) =−<T,C _(e)(i+1)−C _(e)(i)> where D_(i) may be an estimation for the derivative of blood pressure signal at time i: BP(t)=Σ_(j=1 . . . t) D _(j)

Finding the pulse rate from the signal BP may be done using previous methods described herein. The function T[ ] may be a linear approximation of the transformation function between the output signal and the input signal for a particular earphone and/or ear canal. Optionally, T[ ] is an approximation function of order two or more, for example, a quadratic function is used.

Algorithm Description

When the audio played is A[ ] and the audio recorded by the transducer is E[ ], then: E=C _(t) *A+C _(e) *C _(t) *A where C_(t)[ ] may be a short vector of coefficients such that the audio played by the transducer is C_(t)*A. C_(t) is constant and can be calibrated by recording and playing a sound when the earphone is not inside the ear canal.

C_(e)[ ] is the frequency response vector of the ear canal. When an audio signal X is being played inside the ear, the signal C_(e)*X is being recorded by the transducer. C_(e)[ ] is a result of X being echoed by the ear canal.

The algorithm may use consecutive short time frames to estimate the frequency response vectors, where C_(e)(i) may be the vector corresponding to the i-th frame. The volume derivative of the ear canal may be a function of the difference between consecutive time frames. This function, being approximately linear, may estimate the volume derivative of the ear canal at time I, such as <T,Δ_(i)>, where Δ_(i)=C_(e)(i+1)−C_(e)(i). Thus the derivative of the blood pressure signal at time i may be <T,Δ_(i)>. The derivative at each time frame may estimate the blood pressure signal, and specifically the pulse rate.

According to some embodiments of the present invention there are provided computerized methods, for a client terminal to measure temperature using an audio output transducer, such as an earphone speaker. To measure temperature using an audio transducer, the audio transducer may be connected simultaneously to an input mixer and to an output mixer of an audio processing integrated circuit. The output audio signal played by the output transducer and the input audio signal recorded from the output transducer when acting as a microphone may be used to compute the temperature. For example, when earphones worn by a user are connected to a client terminal using a soundcard which allows simultaneous output and input paths to and from the earphones, the body temperature of the user is measured. In this example, a calculation of body temperature is performed using the client terminal. The audio output transducer of an earphone may be used simultaneously to output an output audio signal and to record an audio signal. The audio output signal played by the output transducer may be any audio output signal. For example, the output audio signal is a music signal, voice signal, and the like.

The temperature measured may be the temperature of the surrounding environment of the transducer, which may vary a lot. For example, the temperature measured is the average temperature of the surrounding of the membrane and the average temperature of the surrounding of the back of the output transducer. These two temperatures may be very different, for example, in the case of earphones in which the temperature surrounding the membrane is the temperature of the inner ear of a user, while the surrounding temperature of the back cavity is the ambient temperature of the user's outer ear.

An audio transducer may transmit an audio output signal, denoted A[ ], simultaneously with recording an audio signal, denoted E[ ]. For example, E is an audio signal recording using the output transducer as a microphone, and the recorded signal E includes the recording of the audio output signal, A. The vectors A and E may be used to calculate the temperatures of the front and back of the corresponding output transducer. Optionally, the temperatures of the audio output transducer may be calculated immediately by the client terminal or may be stored, optionally transferred, and calculated at a later time, and optionally at a remote location.

The frequency response between A[ ] and E[ ] may be used to calculate the temperature. The physical principle that allows calculating the front and back temperature of the output transducer may be the previously described frequency response changes as a function of temperature. These frequency response changes may be different for temperature changes of the front and back of the transducer, thereby allowing differentiation between the two temperatures.

For example, reference is now made to an exemplary function for calculating temperature using the frequency response between A[ ] and E[ ]. The frequency response C_(tf0,tb0) is measured at basis temperatures tb₀ and tf₀ of the back and front of the output transducer respectively. The frequency response C_(tf0+Δ,tb0) and C_(tf0,tb0+Δ) are measured at temperatures that are Δ different from tf₀ of the front of the transducer or Δ different from tb₀ of the back of the transducer and the linear transformation T_(Δ,0) between C_(tf0,tb0) and C_(tf0+Δ,tb0) and the linear transformation T_(0,Δ) between C_(tf0,tb0) and C_(tf0,tb0+Δ) are thus determined. Since T_(Δ,0) and T_(0,Δ) may be the linear transformations corresponding to changes of Δ of the front or back of the speaker respectively, and we assume they are nearly constant for temperatures close enough to tf0 and tb0, by iteratively applying T_(Δ,0) and T_(0,Δ) to C_(tf0,tb0) we may estimate the frequency response at new temperatures tb₀+k_(b)·Δ and tf₀+k_(f)·Δ. By reversing this process, a measured frequency response may be used to calculate back and front temperatures that would produce this frequency response.

For example, frequency responses are measured at 25 degrees centigrade for both front and back of the output transducer and found to be flat with −2.0 dB attenuation at 5 kHz. The frequency response measured at 25.5 degrees centigrade for the back of the output transducer may be flat with −2.5 dB attenuation at 5 kHz. The frequency response measured at 25.5 degrees centigrade for the front of the output transducer may be flat with −2.2 dB attenuation at 5 kHz and +0.5 dB attenuation at 3 kHz. The frequency response measured at unknown temperatures tb₀+k_(b)·Δ and tf₀+k_(f)·Δ of the output transducer may be flat with −6.4 dB attenuation at 5 kHz and +6.0 dB attenuation at 3 kHz. By finding the number of times, k_(b) and k_(f), the two linear transforms need to be applied, the temperatures for the front and back may be calculated as 37 and 27 degrees centigrade, respectively.

For brevity, the following are additionally defined:

C₀[N] denotes a transducer coefficients vector at baseline temperatures tf₀, tb₀ with tb₀ being the temperature in the back of the transducer and tf₀ being the temperature at the front of the transducer.

T_(Δ,0)[N][N], T_(0,Δ)[N][N] denotes linear transformations of the transducer coefficient vector such that T_(Δ,0) ^(k1)(T_(0,Δ) ^(k2)(C₀)), are the transducer coefficients at temperatures tb₀+k₁·Δ and tf₀+k₂·Δ at the back and front respectively, where Δ is the temperature step used to measure the linear transforms and k₁ and k₂ are the number of temperature steps. The linear transforms for both the front and back temperatures are applied iteratively k₁ and k₂ times on C₀ to reach the actual measured signal E.

∥x∥ denotes the l² norm of x

x*y denotes the convolution of x and y.

tf, tb denote the temperature at the front and back respectively of the output transducer

H_(f), H_(b) denote heat transfer coefficients of the front and back of the output transducer respectively.]

The method may estimate the temperatures tf, tb to be tb₀+k₁·Δ and tf₀+k₂·Δ, using the function: k ₁ ,k ₂=argmin ∥T _(Δ,0) ^(k1)(T _(0,Δ) ^(k2)(C ₀)*A−E∥ ²

Optionally, tf and tb may be found by solving D=argmin ∥D*A−E∥² using linear equations of the derivative of D equal to 0, after which we find k₁, k₂ such that k₁,k₂=argmin ∥T_(Δ,0) ^(k1)(T_(0,Δ) ^(k2)(C₀))−D∥².

Optionally, a calculation of temperatures is performed using two different temperature step resolutions for T_(Δ1)[N][N] and T_(Δ2)[N][N], where Δ₂>>Δ₁. In this case D may be calculated as before, and k₁, k₂ calculated such that k₁,k₂=argmin ∥T_(Δ1) ^(k1)(T_(Δ2) ^(k2)(C₀))−D∥². The different resolution steps allow better differentiation between the effects of the front and back temperatures on the coefficient vector.

Optionally, the algorithm may use a few sets of basis coefficients. Namely C₀[N], . . . , C_(s)[N] which are the transducer coefficients at temperatures tb₀, . . . , tb_(s) and tf₀, . . . , tf_(s). In this case D may be calculated as before, but tf/tb may be calculated using: tf,tb=argmin Σ_(i=0, . . . ,s) ∥T _(Δ,0) ^((tb−tbi)/Δ)(T _(0,Δ) ^((tf−tfi)/Δ)(C _(i)))*A−E∥ ² which may be calculated by solving linear equations. Optionally, any number of basis temperatures may be used.

Optionally, the temperature is calculated with two or more pairs of linear transformations. For example, T_(Δ1,0)[N][N], T_(Δ1′,0)[N][N] and T_(0,Δ2)[N][N], T_(0,Δ2′)[N][N] such that Δ1′>>Δ1 and Δ2′>>Δ2. In this case D may be calculated as before, but k₁,k₁′,k₂,k₂′ calculated using: k ₁ ,k ₁ ′,k ₂ ,k ₂′=argmin ∥T _(Δ1′,0) ^(k1) ′·T _(Δ1,0) ^(k1)(T _(0,Δ2′) ^(k2) ′·T _(0,Δ2) ^(k2)(C ₀))*A−E∥ ²

Optionally, different basis temperatures and different temperature resolution steps are be used together determine the target temperature.

Optionally, tb and/or tf are calculated at two or more times, and the values extrapolated to a future steady state temperature value. For example, A and E are collected continually and segmented into windows, with a tf and/or tb value calculated for each window. For example, the process may be repeated x times, and the final tf and/or tb is then taken to be the extrapolation of the x intermediate results.

An issue with temperature measurements as described herein may be that the temperature measured is that of the back and front of the transducer, and not the temperature of the inner ear or the environment. It may take the transducers temperature a long time to reach the temperatures of its surrounding. For this reason, the speed of temperature change of the transducer may be used to estimate the temperatures of its surrounding. Optionally, the heat transfer coefficients Hb and Hf are used and if the front and back temperatures are tf,tb and a second later are tf′,tb′ the surrounding temperatures are δb=Hb·(tb′−tb) and δf=Hf·(tf′−tf).

Optionally, the final steady state temperatures are extrapolated using an exponential function and heat transfer coefficients.

Reference is now made to FIG. 1F, which is a schematic illustration of a user interface to record a signal from an earphone output speaker, compute signals and/or measures data, and outputting the data, according to some embodiments of the invention. The user interface may contain a region for a command menu 191. The user interface may contain a region for measurement display 192 including measurements of body temperature, ambient temperature, pulse rate, heart signal, phone information, call information, noise reduction metrics, and the like. The user interface may contain a region for user defined buttons 194. The user interface may be presented on a display of a client terminal 193. For example, the display 193 is the screen of a smartphone, personal computer, laptop, music player, tablet, and the like.

The methods as described above may be used in the fabrication of integrated circuit chips.

The flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems that perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

The descriptions of the various embodiments of the present invention have been presented for purposes of illustration, but are not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein was chosen to best explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

It is expected that during the life of a patent maturing from this application many relevant earphone will be developed and the scope of the term earphone is intended to include all such new technologies a priori.

As used herein the term “about” refers to ±10%.

The terms “comprises”, “comprising”, “includes”, “including”, “having” and their conjugates mean “including but not limited to”. This term encompasses the terms “consisting of” and “consisting essentially of”.

The phrase “consisting essentially of” means that the composition or method may include additional ingredients and/or steps, but only if the additional ingredients and/or steps do not materially alter the basic and novel characteristics of the claimed composition or method.

As used herein, the singular form “a”, “an” and “the” include plural references unless the context clearly dictates otherwise. For example, the term “a compound” or “at least one compound” may include a plurality of compounds, including mixtures thereof.

The word “exemplary” is used herein to mean “serving as an example, instance or illustration”. Any embodiment described as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments and/or to exclude the incorporation of features from other embodiments.

The word “optionally” is used herein to mean “is provided in some embodiments and not provided in other embodiments”. Any particular embodiment of the invention may include a plurality of “optional” features unless such features conflict.

Throughout this application, various embodiments of this invention may be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible subranges as well as individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed subranges such as from 1 to 3, from 1 to 4, from 1 to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 3, 4, 5, and 6. This applies regardless of the breadth of the range.

Whenever a numerical range is indicated herein, it is meant to include any cited numeral (fractional or integral) within the indicated range. The phrases “ranging/ranges between” a first indicate number and a second indicate number and “ranging/ranges from” a first indicate number “to” a second indicate number are used herein interchangeably and are meant to include the first and second indicated numbers and all the fractional and integral numerals therebetween.

It is appreciated that certain features of the invention, which are, for clarity, described in the context of separate embodiments, may also be provided in combination in a single embodiment. Conversely, various features of the invention, which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable subcombination or as suitable in any other described embodiment of the invention. Certain features described in the context of various embodiments are not to be considered essential features of those embodiments, unless the embodiment is inoperative without those elements.

Although the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the spirit and broad scope of the appended claims.

All publications, patents and patent applications mentioned in this specification are herein incorporated in their entirety by reference into the specification, to the same extent as if each individual publication, patent or patent application was specifically and individually indicated to be incorporated herein by reference. In addition, citation or identification of any reference in this application shall not be construed as an admission that such reference is available as prior art to the present invention. To the extent that section headings are used, they should not be construed as necessarily limiting.

This specification generally describes systems, methods, devices, and other techniques for processing audio signals. In some implementations, these techniques may be performed using earpieces (e.g., headphones or earbuds) by using a same electroacoustic transducer in the earpiece to both output, as a speaker, a played audio signal and to sense, as a microphone, an aural signal that can be recorded by an audio processing device. In some examples, an audio processing device can process an audio signal sensed by an earpiece and compare that sensed audio signal to an audio signal that is played at the same time to determine whether the earpiece is currently located at a user's ear. In some examples, an audio processing device can process an audio signal sensed by an earpiece to perform an authentication procedure in which a user's identity is verified based on acoustic characteristics of a user's ear. In some examples, an audio processing device may perform active noise cancellation by detecting a known audio signal that occurs in ambient noise of an environment of a user, and by using a pre-recorded instance of the detected audio signal to modify a source audio signal that a user is listening to through a headset.

Referring to FIG. 2A, a conceptual diagram is shown of a user 272 listening to a source audio signal s being played through earbuds 276. The source audio signal s is played by an audio processing device 274, which in this example is a smartphone. The earbuds 276 are lodged in the user's ear 276 so as to form an acoustic chamber by which the user 272 can listen to the source audio signal s. The source audio signal s may carry any of a variety of audio content, such as music, speech, a telephone call, or an audio track from a movie, television show, or other video or media content.

As shown in the enlarged area 278, the earbud 276 is capable of both outputting the source audio signal s and sensing an aural audio signal r. In particular, the earbud 276 includes an electroacoustic transducer that converts electrical signals corresponding to the source audio signal s to soundwaves that can be heard by the user 272. By converting the electrical energy to acoustic energy (i.e., soundwaves), the electroacoustic transducer functions as a speaker. However, the electroacoustic transducer is also mechanically sensitive to acoustic energy in its environment, which causes the electroacoustic transducer to vibrate and thereby generate electrical signals. Accordingly, the electroacoustic transducer is also capable of sensing an aural audio signal r, and in some implementations may even output the audio source signal s while simultaneously sensing the aural audio signal r. In some examples, the electroacoustic transducer may include a diaphragm that moves back and forth to generate soundwaves due to pressure imparted on air located in front of the diaphragm. Electrical signals may drive movement of the diaphragm using any of a variety of technologies such as by coils wound around electromagnets or piezoelectric crystals.

Generally, the aural audio signal r is the audio signal that results in a space in which the earbud 276 is located when a source audio signal s is played through the earbud 276. For example, if a microphone were placed adjacent to the earbud 276 while the earbud 276 lodged in the user's ear played a source audio signal s, the signal captured by that microphone would correspond to the aural audio signal r. Of course, the aural signal r would predominantly reflect the source audio signal s played in the space, but it may further reflect other factors such as intrinsic characteristics of the earbud 276 and the unique acoustic properties of the user's ear that at last partially define the space in which the source audio signal s is played. It is noted that, for purposes of illustration, the enlarged view 278 in FIG. 2A shows the earbud located externally of the user's ear, although in practice, the user 272 would typically listen to an audio signal s with the earbud 276 lodged within his or her ear.

In some implementations, the audio processing device 274 may be configured to both play the source audio signal s and to record the aural audio signal r as output and sensed, respectively, by the same electroacoustic transducer of earbud 276. A sound card or other processing circuitry of the audio processing device 274 may be configured to output and record audio signals via a same electroacoustic transducer (e.g., of an earpiece that does include a dedicated microphone distinct from a speaker of the earpiece). For example, an electronic resistance component may be connected between one or more conductors of a circuit that electrically interfaces an earpiece transducer and an audio processing device. The placement of the resistor may form a voltage divider that provides a location in the electrical interface from which an electrical signal corresponding to the aural audio signal r can be sensed and, e.g., digitally sampled and recorded. Processing circuitry of the audio processing device 274 may drive an electrical signal to the electroacoustic transducer for playing a source audio signal s, while simultaneously recording the aural audio signal r. In some implementations, the processing circuitry may switch (e.g., at a high frequency) between alternate modes for playing a source audio signal s and recording the aural audio signal r. The switching may occur at a sufficiently high frequency so that the user 272 does not perceive any disruption in the playing of source audio signal s.

In some implementations, the earbuds 276 may be part of a premium headset that, for example, includes a dedicated microphone. The dedicated microphone may be used, for example, to record an aural audio signal r or to record environmental noise, as may be done for active-noise cancellation, for example. For instance, the dedicated microphone may be an embedded microphone (e.g., 210 a, 210 b) or an external microphone may be employed (e.g., microphone 212).

Parameter Determination

Various ones of the techniques described herein involve determining parameters associated with audio signals, earpieces, a space in which the earpiece is located (e.g., a user's ear canal), or a combination of these. Some of these parameters are reflected in the following model (Equation 1), which represents an aural audio signal r, as recorded by an audio processing device, as a function of these parameters. r=s*(w0+T·wΔ+wa)+e+n   (Equation 1)

-   -   Note: the * operator denotes convolution

The parameters in the model of Equation 1 generally indicate the following:

TABLE 1 r Digital samples recorded from aural audio signal sensed by earpiece s Digital samples of source audio signal to be played through earpiece e Environmental noise that occurs in a space in which the earpiece is located (e.g., background or ambient noise) n Electrical noise resulting from audio processing circuitry w0 Model of the electrical echo of the earpiece at baseline temperature T₀ (e.g., in Kelvins) wΔ Model of the temperature-dependent electrical echo of the earpiece wa Model of the acoustic echo of a space in which the earpiece is disposed T Temperature difference from T₀

Thus, the model of Equation 1 indicates that the recorded aural audio signal r is a function of three audio signals: (1) source audio signal s played by the audio processing device, (2) environmental noise e, and (3) electrical noise n of the audio processing device. However, the source audio signal s may be distorted due to three factors, and this distortion is represented by the convolution of s with (w0+T·wΔ+wa). The parameters w₀ and w_(Δ) are intrinsic parameters of the earpiece, and specific to the design of a given earpiece. Thus, an earbud that fits within an ear may have different parameters w₀ and w_(Δ) values from an earphone that covers an ear. Likewise, a first earbud of a particular model by a particular manufacturer may have different w₀ and w_(Δ) parameters from a second earbud of a different model by a different manufacturer. These parameters generally indicate how the geometry and overall configuration of an earpiece act to modify (e.g., distort) the audio signal s when played through that earpiece. The w₀ parameter indicates how the earpiece modifies an audio signal sat a baseline temperature T₀ (e.g., 20 degrees Celsius), while the w_(Δ) parameter indicates how the earpiece modifies an audio signal s as a function of a temperature difference from T₀.

In general, both w₀ and w_(Δ) represent a transformation characteristic of the audio signal s imparted by the earpiece independent of a space in which the earpiece is disposed. In some implementations, w₀ and w_(Δ) each comprise a plurality of values (e.g., tens or hundreds of values) that collectively indicate respective impulse response characteristics of the earpiece. For example, w₀ can indicate the impulse response function of the electrical echo of the earpiece, and w_(Δ) can indicate the temperature-dependent impulse response function of the electrical echo of the earpiece.

A simplified way of describing the impulse response functions is to imagine the echo that results when an impulse tone is provided to the earpiece. For example, assuming that that the system samples at 1000 Hz, then the system would sample the amplitude of the earpiece voltage every 0.001 seconds. If an impulse tone was output at time 0, the impulse response may record the echoes that the earpiece would hear and that were due to the output of the impulse tone, in this example being recorded as an amplitude measurement every 0.001 seconds. As such, the impulse response may be considered a vector or array of values, one recorded each 0.001 seconds after the playing of the impulse function. This echo can be determined to have a fixed characteristic that is based on the characteristics of the earpiece (e.g., w₀) and a variable characteristic that is based on of the earpiece temperature (e.g., T·wΔ).

The echo is also affected by an additional transformation characteristic that represents the acoustic characteristics of the space in which the audio signal is played, such as the user's ear canal (e.g., w_(a)), although this transformation characteristic is described in greater detail later and may be disregarded for certain measurements. Overlooking environmental noise and electrical noise for a moment, it can be seen how the recording r taken using a transducer would be the combination of sound s that was played using the transducer, convoluted with multiple impulse responses that indicate how long it takes for that sound to echo back to the transducer for recording (possibly appearing at multiple different times due to different echoes on different surfaces of the user's ear and the earpiece), and how loud that echo is at various times.

Returning now to discuss the transformation characteristics, the intrinsic parameters of the earpiece (w₀ and w_(Δ)) may be pre-defined and stored in a database that stores intrinsic parameters for a plurality of different earpieces. The audio processing device may identify these parameters from the database (e.g., from user input indicating the make and model of his or her earpieces or based on an automatic detection capability). In some implementations, the intrinsic parameters may be calibrated at a factory or laboratory and made accessible to a population of users. In some implementations, the intrinsic parameters may be calibrated by individual users with their respective audio processing devices.

In some implementations, the environmental noise signal e is determined by recording the audio signal that results when the earpiece is located in position and no audio source signal s is played through the earpiece. In some implementations, the environmental noise signal e may be recorded from a signal sensed by a second microphone other than the electroacoustic transducer of the earpiece, such as an external microphone located in the environment of the user of the earpiece. In some implementations, the environmental noise signal e is calculated after the system has determined the temperature T and the acoustic echo parameter w_(a), since the other variables and constants may be known or already calculated (the circuit board noise N may either be known, or the combination of the environmental noise signal e and the circuit board noise N may be calculated in combination).

The acoustic echo parameter w_(a) may indicate an acoustic characteristic of a space that the earpiece is located in when playing audio source signal s. For instance, the w_(a) parameter indicates how the physical space in which the earpiece is disposed imparts distortion on audio signal s, and is generally independent of how the earpiece itself imparts distortion on audio signal s. The size, shape, configuration, and material of the space in which the earpiece is located may all affect the w_(a) parameter. Accordingly, when the same earpiece plays a source audio signal s in different spaces, the source audio signal s may be distorted in somewhat different ways based on the particular characteristics of the respective spaces. The acoustic echo parameter w_(a) may be derived when various other values are known, such as the audio source signal s, the aural audio signal r, and the transformation characteristics w₀ and T·w_(Δ).

As is described in greater detail herein, the acoustic echo parameter w_(a) may be applied in different contexts, for example, to generate unique acoustic signatures for users based on the configurations of users' ears that form a space for an earpiece, to verify the identity of users, to detect whether an earpiece is disposed in the ear of a user, and to determine a temperature of an earpiece or a space within which the earpiece is located. In some implementations, the acoustic echo parameter w_(a) can comprise a plurality of values (e.g., tens or hundreds of values) that collectively indicate an impulse response of the space in which an earpiece is located. The impulse response function can thus model the transformation or distortion of audio signal s resulting from the acoustic characteristics of the space in which the earpiece is located.

In some implementations, an audio processing device may determine values for the temperature T and the acoustic echo parameter w_(a) by solving Equation 1 for the values, once other relevant parameters have been identified. An example process 600 for determining or solving for T and w_(a) using the above-described Equation 1 is represented in the flowchart of FIG. 6. In some implementations, the process 600 may be performed by an audio processing device using conventional earpieces (e.g., earbuds or earphones) having an electroacoustic transducer to output and sense audio signals. To derive T and w_(a) for a given space, the earpiece is located in that space while an audio source signal s is played through the earpiece (stage 602) and while an aural signal r is recorded from electrical signals generated by the earpiece transducer (stage 604). For example, a user could prompt determination of the acoustic echo parameter w_(a) for one of the user's ears by placing the earpiece in position at the user's ear and selecting a control on the audio processing device that initiates performance of the process 600. In some cases, the values of w_(a) may depend in part on a position and orientation of the earpiece in a space, and so the user may take care to locate the earpiece at or near a desired position in the space for determination of the w_(a) parameter. In some implementations, a space may be associated with multiple sets of values for the w_(a) parameter, each set corresponding to a different position of the earpiece in the space.

At stage 606, the audio processing device identifies the intrinsic earpiece parameters w₀ and w_(Δ). These may be calibrated locally on the audio processing device, stored on the audio processing device, or obtained from a computing system remote from the audio processing device (e.g., an Internet-based server system). The audio processing device may identify values for the intrinsic parameters that specifically apply to the earpiece worn by the user. These values may not change based on position of the earpiece or location of the earpiece in a space.

At stage 608, the audio processing device selects a first segment of the audio source signal s and a corresponding segment of the aural signal r for processing in an initial iteration. The selected segment of the aural signal r corresponds to the first segment of the audio source signal s in that the selected segment of r indicates the aural signal that occurred during a same period of time in which the first segment of audio signal s was played and output into the space by the electroacoustic transducer of the earpiece. For example, if the system is playing and recording audio at 1000 Hz, the selected r and s segments may include the voltage of the played signal and the voltage of the recorded signal over a 0.001 second interval of time or recorded every 0.001 seconds.

At stage 610, the audio processing device determines a source-reduced aural signal r_(diff). The source-reduced aural signal r_(diff) can be computed by subtracting, from the selected segment of recorded aural signal r, the convolution of the selected segment of the audio source signal s and w₀ (i.e., rdiff=r−s*w0). As may be apparent from analyzing Equation 1, rdiff represents the portion of the recorded sound that excludes the w₀ effect of the earpiece on the recording.

At stage 612, the audio processing device determines the temperature-dependent aural signal r_(Δ) as the convolution of the selected segment of the audio source signal s and w_(Δ) (i.e., rΔ=s*wΔ). As may also be apparent from analyzing Equation 1, r_(Δ) represents the portion of the recorded sound that excludes the w₀ effect of the earpiece on the recording.

At stage 614, the audio processing device can then determine a temperature T (either an absolute temperature T or a temperature that represents an offset from the baseline temperature T₀). This temperature T can be determined by identifying a value for T that minimizes the difference between r_(diff) and the convolution of T and r_(Δ) (i.e., T=argmin_(T)(r_(diff)−T*rΔ)). In some implementations, the value of T that minimizes this expression can be determined using a minimum least squares estimation technique. The identified value of T can be the determined temperature of the earpiece. As may be apparent from analyzing Equation 1, this identification of T does not account for the effect on the recorded signal that w_(a), e, and N may impart. This may be because w_(a) may be assumed to be optimal and e and N may have negligible effect on the identification of T during the initial determination of various coefficient values.

At stage 616, upon determining a value for T (stage 614), the audio processing device then determines values for the aural signal acoustic echo r_(a). The aural signal acoustic echo is generally the component of the recorded aural signal r that results from audio played by the earpiece, and is the distortion imparted on the audio source signal s as a result of the acoustic characteristics of the the earpiece (e.g., not accounting for w_(a), e, and N. The aural signal acoustic echo r_(a) can be computed by identifying the recorded signal r, and subtracting from it (1) the convolution of the selected segment of the audio source signal s and w₀ and (2) the convolution of T, the selected segment of the audio source signal s and w_(Δ) (i.e., ra=r−s*w0−T*s*wΔ).

In practice, the values of T, and thus of r_(a), tend to change rapidly. An earpiece may warm up, for example, the longer it is lodged in a user's ear, or based on increasing intensity of the source audio signal s during different segments of the song or as a result of the user increasing volume for playing the source audio signal s. To account for these rapidly changing values, the process 600 may determine a new value of T and r_(a) for each of multiple small segments of the audio source signal s and the recorded aural signal r before computing the values of the acoustic echo parameter w_(a). For example, T and r_(a) may be calculated for small segments of r and s (e.g., between 0.05 and 2 seconds), and then w_(a) calculated after a longer time has passed (e.g., 2-10 seconds) based on values determined from multiple segments. These values may be averaged or otherwise combined at stage 622. In some implementations, the values of w_(a) can be recalculated every 0.2 seconds (i.e., the size of the interval of r_(a) every 0.2 seconds). In some implementations these intervals for calculating w_(a) can be even smaller, such as every 0.05 or 0.1 seconds. The values of r_(a) calculated at each interval can be combined by concatenation, i.e. by dividing r_(diff) into different segments, finding the corresponding value of T for each segment, calculating r_(a) and concatenating them. If additional segments of the source signal s and aural signal r remain to be processed before determining w_(a) (stage 622), then at stage 620 the audio processing device selects the next segment of the signals s and r and returns to stage 610 for additional iterations. The process 600 may continue these iterations until a threshold number of iterations has passed or until another condition is satisfied.

At stage 622, the audio processing device then determines the value of the acoustic echo parameter w_(a). In some implementations, the value of w_(a) can be computed as the value that minimizes the expression ∥s*wa−ra∥. The values that minimizes this expression may be determined using various techniques, such as minimum least squares estimation. As may be apparent from analyzing Equation 1, the determination of the acoustic echo parameter w_(a) may not account for the values of e and N.

Once T and w_(a) have been calculated, e and N may be computed. The system may wait a determined amount of time before performing such a computation, in order to let the temperature of the earpiece level out (e.g., at least 5 or 10 seconds). At this point, all other values of Equation 1 may be known, and the combination of e and N may be calculated. It may be possible to separate the value for e from the value for N if the system can determine characteristics of either signal (e.g., using another microphone to record a variation of e that is common to both recordings).

Referring back to FIG. 2B, a block diagram is shown of an example audio processing device 202 that may be configured to perform operations of the various methods described herein. The device 202 may be, for example, a portable media player, a smartphone, a tablet computing device, a wearable computing device, a notebook or desktop computer, a television, or other types of computing devices that generally are capable of playing, recording, and processing audio signals.

The device 202 includes an audio processor 220 having a player 222 for playing audio source signals and a recorder 224 for recording signals sensed by a microphone 212. An earset 204 having a pair of earpieces 206 a and 206 b (including respective electroacoustic transducers 208 a, 208 b and optionally separate microphones 210 a, 210 b) may connect to the audio processing device 202 via port 226 (e.g., a standard 3.5 mm audio jack). The earset 204 may be a conventional, off-the-shelf device that does not have a dedicated microphone built into the earpiece. In some implementations, the earset 204 may be a specialized device that, for example, includes built-in microphones 210 a, 210 b. In some implementations, the audio processing device 202 may include a controller 218 that coordinates operations performed by the device; an authentication engine 228 that performs aural-based authentication of users; an acoustic modeling engine 238 that generates values of acoustic echoes w_(a) and acoustic signatures for users; an external noise detector 236 for identifying ambient sounds and the occurrence of pre-recorded audio signals in the ambient sounds; and a noise cancellation engine 240 for performing active noise cancellation using information about pre-recorded audio signals identified by the external noise detector 236. The device may further include a communications interface 242 that communicates over a network 216 with a server 214, e.g., to identify pre-recorded sounds and to obtain pre-stored models of acoustic echoes w_(a). In some implementations, the audio processing device 202 may have fewer than all of these components, or may include only particular combinations or subsets of these components. As an illustration, in those examples in which the earphones are connected to the audio processing device via a BLUETOOTH or other wireless connection, at least some of the audio processing may be performed by circuitry at the headphones (e.g., the codec, the digital-to-analog output conversion, and the input analog-to-digital conversion may be performed at the headphones). The external microphone 212 may also be connected directly by permanent hard-wire connection to the audio processing circuitry in the headphones, rather than being connected to the audio processing device 202 through a permanent hard-wire connection (e.g., not through a releasable 3.5 mm audio jack). The details of operations performed by the audio processing device 202 are described in the following sections.

Configuring Simultaneous Playing and Recording

A system can use a single transducer to both play and record audio. By way of example, a transducer in an off-the-shelf earset may be positioned so that it produces sound directed toward the ear canal, and so using that transducer also as a microphone may be useful given its orientation toward the ear canal to receive sound, as will be understood in view of intended applications for the technology described in this document that are described below. The use of an earset transducer to both play and record audio may be accomplished by either alternating between the playing and recording functions, or by playing and recording at the same time. In the former, the sound card output port and the sound card input port may be both connected to the transducer, and the sound card may alternate between outputting a signal to the transducer and recording a signal that is generated by the transducer, for example, by repeatedly playing audio for 200 mS and then recording audio for 10 mS.

Regarding the second option, it is possible to both play and record audio at the same time. Doing so enables a computing system to analyze differences between the played audio and the recorded audio, which can be helpful because it allows a computing system to determine characteristics of the environment in which the audio was played (e.g., a temperature of the environment, sounds from the environment, and audio-reflective characteristics of the environment, such as shape). To enhance simultaneous playing and recording of audio, however, it is helpful to modify the typical standard connection between the earpiece transducer and the sound card (e.g., the sound card codec). The modification can include inserting a resistor between the transducer and either the audio circuit output or input. In effect, this insertion may be the same as inserting the resistor between the audio circuit output and input ports. This inserted resistor is illustrated in FIG. 2C as R_(ADDED). Before discussing the benefits provided by the addition of this resistor, this disclosure provides a brief, and somewhat simplified, overview of transducer operation.

Referring now to FIG. 2C, the figure shows a codec 250 on the left, which represents the circuitry that can output an electrical signal to a transducer (e.g., through the V_(PLAYED) output port) and that can input/analyze an electrical signal received from the transducer (e.g., through the V_(RECORDED) input port). The codec may be located in a mobile device (e.g., a phone) or may be located in the headset (e.g., in the circuitry of Bluetooth-connected earphones). To the right of the figure is an earpiece 260 which includes a transducer. In this example, both the V_(PLAYED) and V_(RECORDED) ports are connected to the transducer which is being used both in a speaker configuration and a microphone configuration. This contrasts with a typical operation which would involve one of the V_(RECORDED) port or V_(PLAYED) port being connected to the transducer by itself, depending whether the transducer was to be used as a speaker or a microphone.

When the transducer is connected as a speaker to the V_(PLAYED) port of the audio circuitry, the transducer moves to create sound waves according to the voltage that is output at V_(PLAYED). Some discussion regarding the construction and functioning of a typical audio transducer may be helpful to explain how sound is created and recorded, and how the configuration described herein enhances simultaneous playing and recording of audio. One of the main components of a typical transducer is the cone. This is the portion of the transducer that moves back and forth to create sound waves and is what is seen when viewing the front of a speaker. It can be made of various flexible materials such as paper, paper composites and laminates, or plastic materials. The fixed frame of the speaker within which the cone moves is called a basket, and the cone is connected to the basket by a gasket around the edges, which may also be a paper, plastic, or rubber material. At the center of the cone is the coil, which is typically connected to the backside of the cone and is not visible when viewing a speaker from its front. The coil is connected to the cone and can move forward and backward with the cone because the center of the cone at which the coil is connected may be suspended in space (the cone is only connected at its outer circumference). Surrounding the coil, but separated by air, is an electromagnet that is fixed to frame. Applying voltage to the electromagnet can induce an electrical field to cause the coil to attract to the electromagnet. Because the electromagnet may be displaced from the coil, inducing an electrical field may cause the coil to move forward and backward. As such, applying voltage to the electromagnet affects the position of the cone that is connected to the coil. Still, a given voltage may not necessarily correspond to a fixed position of the cone, because the cone may have biasing forces imparted on it by the gasket and flexing properties of the cone. In practice, the voltage or audio signal is typically oscillating to represent the various frequencies that output through movement of the transducer, and the history of voltages applied to the transducer affects its positioning. In this example, the voltage would be provided to the transducer by the audio circuitry through the V_(PLAYED) port.

The position of the transducer, however, is not entirely set by the voltage provided at the V_(PLAYED) port. Indeed, imagine a user pressing on the cone while the transducer is playing audio, or a shock wave hitting the transducer. In both these situations, the position of the cone deviates from that that would be expected without the any external influence. Moreover, the movement of the cone due to any external influences affect the voltage over the electromagnet. Indeed, just as a generator works by moving a component with respect to an electromagnet to induce a voltage signal across that electromagnet, moving the cone and coil of a transducer can induce voltage and an electrical signal across the terminals of an electromagnet. In fact, this is how the circuit that is shown in FIG. 2C could function as a recording device—if the earpiece/transducer was connected only to the V_(RECORDED) port (not the V_(PLAYED) port). In such an example, the pressure waves (e.g., sounds) hitting the transducer would be converted to a voltage by the electromagnet, which would be supplied to the V_(RECORDED) port to enable the codec to sample the changing voltage values at that port and output a digital data stream that represents the sound recorded by the transducer.

As such, it can be seen how connecting the V_(PLAYED) or V_(RECORDED) ports to the transducer, at least one at a time, can enable playing audio or recording audio using that transducer. Connecting both at the same time to the transducer, however, may not be effective, because then the V_(PLAYED) and V_(RECORDED) may be shorted together and would be driven to the same voltage (e.g., through connection with a conductor of a resistance less than 0.1, 0.5, or 1 ohms). Introducing a resistor connected between the V_(PLAYED) and V_(RECORDED) ports (e.g., with a resistance of at least 2, 5, 10, 50, or 100 ohms) and then connecting the transducer directly to one of the V_(PLAYED) and V_(RECORDED) ports (e.g., again with a conductor of the above-described resistance values) allows voltages at the V_(PLAYED) and V_(RECORDED) to differ, enabling V_(RECORDED) to sense how the voltage across the transducer voltage differs from that at V_(PLAYED). In this example, the placement of the resistor is illustrated as being placed between the V_(PLAYED) port and the transducer, with the V_(RECORDED) port being directly connected to the transducer, although alternatively the resistor could also be added to the V_(RECORDED) line and V_(PLAYED) could be connected directly to the transducer.

The addition of the R_(ADDED) resistor allows the voltage at V_(RECORDED) to differ from that present at V_(PLAYED). Since V_(RECORDED) is connected between the transducer and ground, just as with the transducer, V_(RECORDED) is thus able to sense the voltage of the transducer. For example, assume that 5V is present at V_(PLAYED) and the voltage across the transducer would be expected to be 4V due to the voltage division between R_(ADDED) and R_(TRANSDUCER). Should the voltage across the transducer differ from 4V due to movement of the transducer that is influenced by external sounds, for example, with the voltage being 4.1V, V_(RECORDED) will measure this voltage. A computing system is then able to determine that there was a 0.1 V deviation from the expected voltage 4V and the measured voltage at a moment in time. Regularly performing this determination, a computing system can extract the relatively-small, but time-varying signal of the components of the recorded signal V_(RECORDED) that differ from the V_(PLAYED) signal.

In some examples, inserting R_(ADDED) into the circuit may not significantly affect the performance of the transducer, but may lower the amplitude of the voltage provided to the transducer or the voltage recorded at V_(RECORDED), depending whether the resistor is placed on at the V_(PLAYED) port or the V_(RECORDED) port, respectively. This reduction may similarly reduce the sound volume output by the transducer or the volume of the recording. As such, the computing system may be configured to switch the R_(ADDED) resistor in and out of the circuit, for example, only switching the resistor into the circuit when the computing system has been instructed to simultaneously play and record audio. When the resistor is switched out of the circuit, the earpiece port may be connected directly to the appropriate V_(PLAYED) or V_(RECORDED) port with a conductor of minimal resistance, as described above. The computing system may at the same time open a switch that connects V_(RECORDED) to the earpiece, so that V_(PLAYED) and V_(RECORDED) are not shorted together with R_(ADDED) removed.

In some examples, the V_(RECORDED) port may be a port that is typically designated for dedicated microphones (e.g., the microphone that dangles from headphones on the cord intended to capture the user's voice). As such, the computing system may be configured to switch the V_(RECORDED) port to being connected to the same transducer as the V_(PLAYED) port when the computing system has been instructed to simultaneously play and record audio over a single transducer. As such, when headphones may be in their typical operation, the computing system may leave the V_(RECORDED) port open or connected to a different microphone. In such examples, the computing system is able to use a dedicated microphone when available or desired, and can use the same transducer as a speaker or microphone when a dedicated microphone is not available or when it is desirable to use the same transducer for both playing and recording audio.

Referring now to FIG. 2D, the figure shows a schematic with an ADC (analog-to-digital converter) and DAC (digital-to-analog converter) to the left, and a representation of a headphone for a user at the right. Connected between the two is a resistor R. This schematic is similar to that shown in FIG. 2C, with the DAC representing V_(PLAYED), the ADC representing V_(RECORDED), R representing R_(ADDED), and H representing R_(TRANSDUCER) (the ground connection of the codec is not represented in FIG. 2D). A primary difference from the schematic in FIG. 2C is that the ADC includes a positive and a negative terminal that are connected across the resistor R, rather than the ADC connecting to just the earpiece side of resistor R. This configuration may be used in codecs that include differential ADCs with positive and negative terminals, and may represent a differential circuit in which the ADC is able to measure the voltage difference over the resistor R. Such a configuration may provide increased dynamic range in comparison to the configuration that is shown in FIG. 2C, in some implementations. The processing by the codec or another computational device may be similar to that performed by the schematic in FIG. 2C. For example, the voltage over the resistor R may differ from that expected for a given output provided by the DAC, due to pressure waves changing the resistance of the headphone earpiece H. The codec (or another computational device) may be able to determine the effect of these pressure waves on the headphone earpiece by comparing the expected and actual measurements across the resistor R by the ADC.

Referring now to FIG. 2E, the figure shows a schematic with two ADCs, two DACs, and two resistor Rs. This schematic is similar to that presented with respect to FIG. 2D, but shows a two-channel implementation (left and right channels) rather than a one-channel illustration. In short, each channel has its own DAC outputting an audio signal to its respective channel, its own resistor R between the DAC and the corresponding input terminal to the audio jack that goes to the user earpiece (or the wire that goes to the corresponding transducer in wireless implementations that do not include audio jacks), and its own ADC to measure the differential across the resistor R. In this example, there is also an ADC for the microphone input, for example, for a microphone that may be located inline the cord between the audio jack and the earpieces. This particular audio codec may have extra ADC inputs that are available for use to measure the voltage across the resistors R_(R) and R_(L). The ADC positive and negative inputs are reversed in comparison to those in FIG. 2D, but differential circuits may be configured with the positive and negative ACD inputs in differing configurations in circuits.

Aural-Based User Authentication

In some implementations, audio signals played and recorded through one or more electroacoustic transducers of an earpiece may be used to implement an authentication capability that can verify identities of users. Authentication can broadly be divided in two principal phases: (i) enrollment and (ii) verification. These phases are represented in the flowchart of FIG. 3. During the enrollment phase (302), a user interacts with an audio processing device to generate one or more acoustic signatures that are registered with a user's account. An acoustic signature is like a unique fingerprint associated with a user, e.g., resulting from unique geometries of the user's ear canal that provides distinct acoustic characteristics. During the verification phase (304), the audio processing device determines whether features of an aural signal at the user's ear matches an acoustic signature associated with the user (e.g., registered with a user's account), and triggers different actions based on whether a match is determined that verifies the user's identity.

For example, when a user arrives at a login page of a banking website, the user's computing device may automatically perform the aural authentication procedure discussed herein to verify the user's identity in lieu of the user typing credentials into the page. If the user is authenticated, the user may be permitted to log into a portal for a banking account associated with the user.

Aural-based authentication is not limited to single, discrete instances of authentication, however (e.g., a one-time verification of a user's identity to determine whether to grant a user access to a restricted site). In some implementations, the aural techniques discussed herein can be used to continuously and repeatedly authenticate a user over time, e.g., during the course of a restricted activity. For example, while the user is logged into a portal for his or her personal banking account, the user may wear a headset that locates a pair of earpieces at the user's ears. As the user interacts with the banking site, the device may play and record sounds through the headset according to, e.g., process 500 of FIG. 5, to monitor the user's status and continuously verify that an authorized user is present while the banking site is open on the device. If the user removes the headset, the authentication procedure can determine that the authorized user is no longer present and can automatically cause the device to log out of the site, thereby ensuring that a non-authorized user cannot hijack the authorized user's account. In some implementations, if authentication fails, the site may prompt the user to confirm his or her identity or may automatically log the user out of the site immediately or after a defined delay.

FIG. 4 depicts an example process 400 for enrolling a user on an audio processing device, including generating and registering an acoustic signature for the user.

At stage 402, the audio processing device receives input to initiate enrollment. In some implementations, the device may present a user interface that prompts the user to enroll and provides step-by-step instructions for actions required of the user, such as instructions to insert an earbud into the ear, adjust a position of the earbud, confirm that a sound was heard, etc.

At stage 404, the audio processing device plays a source audio signal s through an earpiece. The audio processing device may, for example, drive a diaphragm of an electroacoustic transducer in the earpiece to cause the earpiece to generate soundwaves for the audio signal s. Various types of audio content may be represented by the source audio signal s. In some implementations, the source audio signal s may be a familiar song, podcast, or other audio track that the user has selected to listen to at a given time. In some implementations, the source audio signal s may be white noise that would be audible to the user if the earpiece were located at the user's ear. In some implementations, the source audio signal s may be outside the normal range of human hearing (e.g., above 20 kiloHertz) such that the audio source signal s cannot be heard by the user, even if the earpiece is located at the user's ear. An inaudible source signal s may be beneficial, for example, to enable performance of the earpiece detection procedure without disturbing the user with unwanted sounds or in other environments where the user may prefer silence or minimal noise. In some implementations, an inaudible source signal s can be added to an audible signal that a user has already selected to play on a device (e.g., music or other audio content) without being detected by a user. In some implementations, the audio processing device may provide a physical or virtual interface (e.g., through a graphical user interface presented on an electronic display of the audio processing device), which allows the user to select the type of audio signal s to play for in-ear detection (e.g., white noise, inaudible, or a pre-recorded audible sound signal). The audio signal may be played for a relatively short span of time, e.g., 0.05-3 seconds, or continuously.

At stage 406, the audio processing device records an aural audio signal r of sound that occurs at the user's ear where the earpiece is located while the audio source signal s is played. In some implementations, aural signal r can be recorded by the audio processing device based on information sensed by the same earpiece transducer that outputs the audio source signal s. The audio processing device may simultaneously play the audio source signal s and record aural audio signal r (e.g., by driving the transducer and calculating a voltage of the transducer at the same moment, or by the playing and recording being performed alternately from each other at high frequency in a time-division duplex scheme so that the user does not perceive that the playing is being interrupted by recording, such as alternating each no longer than each 1 ms, 0.1 ms, or 0.01 ms). In some implementations, the audio source signal s and aural audio signal r may actually be played and recorded concurrently, without alternating between the stages. In some implementations, the earpiece may include a second transducer separate from the first transducer, where the second transducer serves as a dedicated microphone and the first transducer is a dedicated speaker.

At stage 408, the audio processing device determines values for the acoustic echo w_(a) (e.g., impulse response of acoustic echo of earpiece) associated with the earpiece's current location during a period of time when the device plays the audio source signal s and records the aural signal r. The acoustic echo w_(a) determined at this stage (408) indicates characteristics of the space in which the earpiece is currently located. An acoustic signature is then generated based on the determined values for the acoustic echo w_(a). In some implementations, the values of the acoustic echo w_(a) themselves form the acoustic signature. In some implementations, the values of the acoustic echo may be further processed, filtered, and/or encrypted to generate the acoustic signature for the user.

In some implementations, the audio processing device may generate during the enrollment phase a set of multiple (e.g., 5-10) acoustic signatures for a user. Different attributes may be assigned to different ones of the acoustic signatures that identify respective contexts of the acoustic signatures. For example, the attributes may indicate a particular earpiece type, make, or model for the acoustic signature that corresponds to the earpiece that the user provides during enrollment. The attributes may further indicate an earpiece side (e.g., whether the earpiece is for the user's left or right ear) and a position of the earpiece at the ear. The audio processing device may, for example, prompt the user to rotate an earbud to different positions in the ear so that a collection of possible signatures can be determined and associated with the user, any of which may be valid during the verification phase depending on the position that the user later places the earbud in his or her ear. At stage 412, the acoustic signature is stored in association with an account of the user.

At stage 414, the audio processing device determines whether to prompt the user for signatures at additional in-ear positions. For example, the audio processing device may require a pre-defined number n of acoustic signatures to be generated and registered for a user to complete enrollment, and the process 400 may continue until that number n of valid signatures is reached. If additional acoustic signatures are required, then the process 400 proceeds to stage 418 and the device prompts the user to adjust the earpiece to a new position. The process 400 then repeats from stage 404 to generate an acoustic signature of the user for the changed position of the earpiece. Once a sufficient set of acoustic signatures has been generated, enrollment is completed (stage 416).

Turning to FIG. 5, a flowchart is shown of an example process 500 for verifying a user's identity (i.e., authenticating a user). The process 500 is generally performed after a user has enrolled and activated aural-based authentication services on a device.

At stage 502, the audio processing device receives instruction to initiate an authentication procedure. The instruction may be in the form of user input to the device, or may be an instruction from an operating system or application on the device, e.g., an application that calls an API associated with an aural-based authentication service.

At stage 504, the audio processing device plays a source audio signal s through an earpiece. The audio processing device may, for example, drive a diaphragm of an electroacoustic transducer in the earpiece to cause the earpiece to generate soundwaves for the audio signal s. Various types of audio content may be represented by the source audio signal s. In some implementations, the source audio signal s may be a familiar song, podcast, or other audio track that the user has selected to listen to at a given time. In some implementations, the source audio signal s may be white noise that would be audible to the user if the earpiece were located at the user's ear. In some implementations, the source audio signal s may be outside the normal range of human hearing (e.g., above 20 kiloHertz) such that the audio source signal s cannot be heard by the user, even if the earpiece is located at the user's ear. An inaudible source signal s may be beneficial, for example, to enable performance of the earpiece detection procedure without disturbing the user with unwanted sounds or in other environments where the user may prefer silence or minimal noise. In some implementations, the audio processing device may provide a physical or virtual interface (e.g., through a graphical user interface presented on an electronic display of the audio processing device), which allows the user to select the type of audio signal s to play for in-ear detection (e.g., white noise, inaudible, or a pre-recorded audible sound signal). The audio signal may be played for a relatively short span of time, e.g., 0.05-3 seconds, or continuously.

At stage 506, the audio processing device records an aural audio signal r that occurs at the user's ear where the earpiece is located while the audio source signal s is played. In some implementations, aural signal r can be recorded by the audio processing device based on information sensed by the same earpiece transducer that outputs the audio source signal s. The audio processing device may simultaneously play the audio source signal s and record aural audio signal r as described above (e.g., with the audio source signal s and aural audio signal r being played and recorded concurrently, without alternating between the stages). In some implementations, the earpiece may include a second transducer separate from the first transducer, where the second transducer serves as a dedicated microphone and the first transducer is a dedicated speaker.

At stage 508, the audio processing device determines values for the acoustic echo w_(a) (e.g., impulse response of acoustic echo of earpiece) associated with the earpiece's current location during a period of time when the device plays the audio source signal s and records the aural signal r. The acoustic echo w_(a) determined at this stage (508) indicates characteristics of the space in which the earpiece is currently located.

At stage 510, the audio processing device compares the values determined for the acoustic echo w_(a) determined at stage 508 with stored acoustic signatures associated with a user. If a match is identified (stage 512), then a specified activity may be permitted to be performed (stage 514), such as logging into a restricted account or unlocking a smartphone. If a match is not identified, then the specified activity may be denied or a different action taken by audio processing device (stage 514).

In some implementations, a device may store acoustic signatures for multiple different people that use the device. The authentication process 500 can then be performed to identify a particular user among the multiple different users who have acoustic signatures registered on the device. For example, a tablet computing device may be shared among different family members in a multi-person family. The device may determine who is interacting with the device based on an aural authentication procedure in which the user places earphones on (e.g., to listen to music, a podcast, a video soundtrack), and the device identifies w_(a) values for the user and compares the w_(a) values against acoustic signatures associated with different ones of the family members. The comparison may reveal which of the family members is currently using the device based on, e.g., whose acoustic signature most closely matched the derived w_(a) values. In some implementations, content may be targeted to a specific user based on the aural identification. For example, a video streaming application may have accounts or profiles associated with multiple people on a device. The video streaming application may use aural-based verification to automatically determine whose account or profile to open. In some implementations, content suggestions or recommendations may be provided to a user based on identification of a given user on a device. For example, the device may maintain records of music or videos played by different users and may correlate the records with respective user accounts or respective acoustic signatures of users. When a person is verified, the device may access the records of media previously played by that person and determine additional content to play or suggest to that person. In some implementations, the verification phase of aural-based on authentication can be performed invisibly to a user. For example, as a user listens to a media file through a headset, the device may continuously or at particular times perform a user verification process to identify the user listening to the media file to collect information about the user's content preferences, to make personalized content selections and recommendations to a user, or to otherwise adapt an experience on the device to the user's personal preferences.

Detection of Earpiece at a User's Ear

In some implementations, an audio processing device may be operable to detect whether an earpiece is located at a user's ear or is located away from the user's ear. For an earbud that is configured to be lodged within an ear, the audio processing device may determine when the earbud has been inserted into the ear of a user or when the earbud is removed from the ear of a user. For an earphone (e.g., from a headphones device), the audio processing device may determine when the earphone has been placed over the ear of a user or has been moved off the ear of the user. As described in the following paragraphs, the detected presence or absence of an earpiece at a user's ear, or the detected change in location of the earpiece relative to the user's ear may trigger specified actions to be performed by the audio processing device or another computing device or system in communication with the audio processing device. For example if, as a user is listening to music or another audio source signal s through his or her audio processing device and the user intentionally removes an earpiece from his or her ear to direct his or her attention to another activity, the audio processing device may detect that the earpiece has been removed from the ear and automatically cause a media player application on the device to pause the music. Later, when the user is ready to begin listening to the music again, the user may simply position the earpiece at the ear to cause the device to automatically resume playback of the music from the same position in the music track where the track had earlier been paused.

Referring to FIG. 7, the depicted flowchart shows an example process 700 for determining the current location of an earpiece vis-à-vis a user's ear, and in particular, whether the earpiece is located at or away from the user's ear. This process may be able to specifically determine whether an earpiece is located in a user's ear, in distinction to merely determining the presence of any object nearby the earpiece. In some implementations, the process 700 may be carried out by the devices and systems described herein, such as audio processing device 202 (FIG. 2B).

At stage 702, the audio processing device plays a source audio signal s through an earpiece. The audio processing device may, for example, drive a diaphragm of an electroacoustic transducer in the earpiece to cause the earpiece to generate soundwaves for the audio signal s. Various types of audio content may be represented by the source audio signal s. In some implementations, the source audio signal s may be a familiar song, podcast, or other audio track that the user has selected to listen to at a given time. In some implementations, the source audio signal s may be white noise that would be audible to the user if the earpiece were located at the user's ear. In some implementations, the source audio signal s may be outside the normal range of human hearing (e.g., above 20 kiloHertz) such that the audio source signal s cannot be heard by the user, even if the earpiece is located at the user's ear. An inaudible source signal s may be beneficial, for example, to enable performance of the earpiece detection procedure without disturbing the user with unwanted sounds or in other environments where the user may prefer silence or minimal noise. In some implementations, the audio processing device may provide a physical or virtual interface (e.g., through a graphical user interface presented on an electronic display of the audio processing device), which allows the user to select the type of audio signal s to play for in-ear detection (e.g., white noise, inaudible, or a pre-recorded audible sound signal). The audio signal may be played for a relatively short span of time, e.g., 0.05-3 seconds, or continuously.

At stage 704, the audio processing device records an aural audio signal r of sound that results in a space where the earpiece is located while the audio source signal s is played. In some implementations, aural signal r can be recorded by the audio processing device based on information sensed by the same earpiece transducer that outputs the audio source signal s. The audio processing device may simultaneously play the audio source signal s and record aural audio signal r, or the playing and recording may be performed alternately from each other, e.g., in a time-division duplex scheme. In some implementations, the earpiece may include a second transducer separate from the first transducer, where the second transducer serves as a dedicated microphone and the first transducer is a dedicated speaker.

At stage 706, the audio processing device determines values for the acoustic echo w_(a) associated with earpiece's current location during a period of time when the device plays the audio source signal s and records the aural signal r. The acoustic echo w_(a) determined at this stage (706) indicates characteristics of the space in which the earpiece is currently located. Depending on whether the earpiece is currently located at or away from the user's ear, the values of w_(a) may vary significantly, thereby allowing determination of the location of the earpiece from the w_(a) values. In some implementations, the audio processing device determines the values of w_(a) according to the process 600 set forth in FIG. 6, as described previously.

At stage 708, the audio processing device accesses pre-stored values for the acoustic echo W_(a-stored) associated with earpieces that were previously determined to be located at an ear of a user. The values of W_(a-stored) are thus representative of values that would be expected if an earpiece is located at the ear of the user. The values of W_(a-stored) may be determined based on analysis of the acoustic echo from previous instances in which the earpiece was determined to be located at (i) the ear of the same user for which the device determined w_(a) at stage 706, (ii) the ears of other users (e.g., users or testers associated with a provider of the in-ear detection service), or (iii) the ears of both the same user from stage 706 and other users. In some implementations, the values of w_(a-stored) may be automatically updated based on updated values pushed to the audio processing device from a server system or based on feedback from the user of the audio processing device indicating whether previous determinations of the location of an earpiece were accurate.

In some implementations, the audio processing device may access different values for w_(a-stored) based on the particular earpiece worn by the user or based on a predicted position of the earpiece. Since the values of the acoustic echo parameter w_(a) may be sensitive to differences among earpiece design and differences in position of the earpiece at the user's ear that impact the acoustic properties of the space in which the earpiece is located, the audio processing device may identify the pre-stored values for w_(a-stored) that most closely match the conditions of the user's earpiece during the course of process 700. For example, the device may recognize that the earset connected to the device are IPHONE earbuds, and may select values for w_(a-stored) that are appropriately correlated with these types of earbuds. In some implementations, the device may store information about the frequencies at which a user has historically positioned an earpiece at his or her ear, and may first access pre-stored values for w_(a-stored) that correspond to one or more positions that the user most frequently places the earpiece at his or her ear. The values of w_(a-stored) may differ from acoustic echoes that were determined from earpieces that were merely placed near non-ear objects or inside of non-ear objects. In other words, the values of w_(a-stored) may be specific to one or more user ears. In some implementations the values of w_(a-stored) may reflect acoustic echoes that were determined from earpieces that were placed near any objects (whether or not ear objects), such that the audio processing device is able to determine whether the earpiece is near any object.

At stage 710, the audio processing device compares the values of w_(a) (derived at stage 706) with the values of w_(a-stored) (derived at stage 708). In some implementations, the device determines a similarity score that indicates how closely the values of w_(a) match the values of w_(a-stored). Generally, a closer match between the values indicates a greater likelihood that the current location of the earpiece is at the user's ear. At stage 712, the audio processing device may evaluate the similarity score with respect to a threshold score. If the similarity score satisfies the threshold (e.g., is greater than or equal to the threshold score), then the process 700 proceeds to stage 714 and the device outputs an indication that the earpiece is in the user's ear. If the similarity score does not satisfy the threshold, the process 700 proceeds to stage 718 and the device outputs an indication that the earpiece is not located in the user's ear. In some implementations, the audio processing device compares one or more values for w_(a) to stored values of w_(a-stored) or predetermined functions, thresholds, parameters, or tolerances, to determine whether the earpiece is near any object (not necessarily an ear). In response to determining that the earpiece is near an object or not near an object, the audio processing device may output an indication to that the earpiece is near an object or not near an object, to trigger a corresponding action.

In some implementations, different actions may be performed on the audio processing device or on another device based on whether the earpiece is determined to be located in the user's ear. For example, a first action may be performed based on identifying that the earpiece is located at the user's ear (stage 716); alternatively, a second action may be performed based on identifying that the earpiece is located away from the user's ear (stage 720). In some implementations, the audio processing device may continuously monitor the location of an earpiece, and an action may be triggered based on identifying that the earpiece has been moved to a user's ear or identifying that the earpiece has been moved away from the user's ear.

Different types of actions that may be performed on the audio processing device or another computing device responsive to determining a location of an earpiece with respect to a user's ear include playing a media file, pausing the media file, stopping the media file, resuming play of a paused media file, activating an electronic display, adjusting a brightness setting of a backlight of the electronic display, transitioning a device into a locked mode, transitioning a device out of a locked mode, initiating a telephone call, ending a telephone call, launching an application, or closing an application. For example, a media player may pause a song if a user's earpiece falls out of the user's ear; a telephone application may end a call, switch to speakerphone or other internal speaker of the device, or generate an alert to parties on a call if the user's earpiece is no longer detected at the user's ear; or a media application may begin playing a song or other media file in response to determining that an earpiece has been moved to a location at the user's ear. In some implementations, for example, when the device detects that the user has inserted the earpiece back into his or her ears, the device may revert to a mode that existed before the earpiece was removed, such as switching back from speakerphone to earpiece use during a telephone call.

Active Noise Control Using Pre-Recorded Sounds

In some implementations, an audio processing device may perform active noise cancellation using pre-recorded sounds. Generally, these techniques allow a device to access a stored instance of a pre-recorded audio signal and use the stored instance of the pre-recorded audio signal to cancel interference or noise caused by the playing of another instance of that same pre-recorded audio signal in an environment of a user. For example, a user may wear earphones during a workout at a gym to listen to songs on his or her personal playlist. The gym, however, may play (or even blast) music through a loudspeaker, and the presence of the gym's loudspeaker music may make it difficult for the user to hear his or her preferred audio content. Accordingly, a microphone associated with the user's audio device (e.g., a microphone that is the same electroacoustic transducer as the transducer that outputs a played audio signal, a separate microphone on the user's headset, a microphone that is external to the audio device and separate from the user's headset, a microphone that is built into the user's headset, or two or more of these microphones) may record an audio signal that identifies environmental noise around the user, which includes the music playing through the gym's loudspeaker. The device may process that recorded audio signal to identify the particular music playing through the gym's loudspeaker (e.g., a Lady Gaga song, a Rolling Stones song, or a Prince song), and then may access a copy of the same music and use that copy to predict in real-time how to cancel noise resulting from the song being played through the loudspeaker in the user's environment.

One notable benefit of using pre-recorded sounds for active noise cancellation is that the latency in generating a modified, noise-cancelled audio signal can be substantially reduced as compared to other active-noise cancellation approaches. This is because the stored instance of a pre-recorded audio signal can effectively serve as a map that the audio processing device can use to predict environmental sound before it even occurs.

An example process 800 for example noise cancellation with pre-recorded sounds is represented in the flowchart of FIG. 8. At stage 802, the audio processing device plays a source audio signal s through an earpiece transducer located at a user's ear. For example, the user may be listening to a podcast, but he or she may be located in a noisy environment such as a restaurant, coffee shop, or public transit. At stage 804, the device captures an audio signal sensed by a microphone connected to the device (e.g., where the microphone could be the same transducer through which the source audio signal s was played). The recorded audio signal contains environmental noise (i.e., external or ambient noise around a user). At stage 806, the device identifies a pre-recorded audio signal p that occurs in the captured environmental noise. By way of example, the pre-recorded audio signal may be a particular song played on the radio as background noise in a shop or restaurant. The device may identify the particular song by accessing a database of pre-recorded audio signals and comparing a sample of the audio signal p that was recorded from the microphone with portions of the audio signals stored in the database. At stage 808, the device accesses a stored instance of the pre-recorded audio signal p′. The device then synchronizes the stored instance of the pre-recorded audio signal p′ with the audio signal p that occurs in the external noise, which can occur in real-time as the song continues to play in the background. At stage 512, the device cancels the pre-recorded audio signal p from the audio source signal s using the pre-recorded audio signal p′. For example, the pre-recorded audio signal p′ (or a processed signal derived from the pre-recorded audio signal p′) may be subtracted in a manner that is synchronized with the background audio signal p, so that the pre-recorded audio signal p′ cancels the distortion imparted on audio signal s by background audio signal p. Additional techniques for performing active noise cancellation are discussed in WIPO Publication WO2014/178054, which is hereby incorporated by reference in its entirety.

In some implementations, active-noise cancellation with a pre-recorded audio signal can be performed as follows, using a common transducer in an earpiece to play and capture noise. The pre-recorded audio signal is represented as p. The signal recorded from the microphone (e.g., the common transducer in the earpiece) is represented as a. Another parameter used in this scenario is w_(room), i.e., the room impulse response, which describes the relationship between p and a. In particular, a is the convolution of w_(room) and p. Note, this example refers to a “room” and a “room impulse response” to refer to the environment of a user, which is often an at least partially closed environment in which a loudspeaker outputs audio content.

The values of the w_(room) parameter may vary as the user moves around the room and can vary depending on characteristics of the room itself in which the user is located. Generally, w_(room) is sensitive to the configuration of a given room where the user is located, the user's position in the room, the loudspeaker's position in the room, and the relative locations of the user (i.e. of the user's microphone) and the loudspeaker. If the location of the user and conditions in the room do not change, the values of w_(room) may remain generally static, but if, on the other hand, the location of the user or other conditions of the room do change, the values of w_(room) may vary accordingly. Generally, for very small intervals of time (e.g., 0.01 seconds, 0.1 seconds), w_(room) will not change significantly from one interval to the next. If the audio processing device has

As the user listens to a source audio signal s, and as one or more microphones (e.g., the electroacoustic transducer of the earpiece lodged in the user's ear) sense audio signal a, the user's audio processing device may continuously and repeatedly re-calibrate w_(room). Once the device determines w_(room),and the device has identified the pre-recorded audio signal p from the environmental noise, the device can predict a as the convolution of p and w_room for a next time interval (e.g., 0.1 seconds, while w_(room) remains relatively constant from the preceding time interval). In some implementations, the audio processing device may re-calculate w_(room) and predict intervals for noise cancellation at even higher frequencies for less latency, e.g., every 0.1-3 milliseconds. Once the device determines a, the device can perform algorithms to “inverse” the signal, such as finding a signal s that when played from the headphones outputs −a, to cancel the background noise.

Temperature Measurement

Using the techniques described in this document, a device may measure temperature using a transducer, for example, one that is located in an earpiece to play audio. The measured temperature may be that of the earpiece, but using various mechanisms described herein, the temperature of a user's ear or of an environment in which the earpiece is located may be inferred. There are various benefits to performing temperature measurement using an earpiece rather than a dedicated thermometer. A main benefit is that earpieces already on the market may be converted into temperature-sensing devices, without any modification of the earpieces being required in some implementations. As such, phones and other devices to which earpieces may be connected can be programmed to sense the temperature of a user or environment without adding a dedicated temperature sensor. Moreover, the techniques described herein are valuable because, even if one designed an earpiece or mobile device to include a temperature-specific sensor (e.g., a thermistor), the heat generated by the user, phone, or earpiece may affect the temperature of that temperature-specific sensor.

Enabling a mobile device to measure temperature with an earpiece serves many beneficial uses. For example, health applications such as fitness trackers may regularly record a user's temperature and plot it over time. As such, a user or computing system can compare recent user temperatures to historical user temperatures to determine whether the user may be falling ill or whether the user's physiology may be changing, and may notify the user of such changes. Statistics may be recorded, for example, to better estimate calories burned by athletes, to alert athletes of possible hyperthermia during a workout, and to estimate days of female ovulation. Such mechanisms may also track environmental temperature as a function of athletic performance (e.g., by charting running times vs. outdoor temperature).

At least two example mechanisms can measure temperatures using a transducer. A first example mechanism is to estimate the temperature of the earphone (e.g., the transducer coil) itself, based on the effect that earphone temperature has on the electrical properties of the earphone. This mechanism uses Equation 1 that is described previously in this document to determine Tat various points in time. Such a mechanism may work for most or all earphones, so long as the system has calibration information for that type of earphone. Still, it may take a while for the earphone to heat or cool to the temperature of its environment, so the mechanisms described herein can analyze the earphone's change in temperature to estimate the future earphone temperature. The future earphone temperature can be compared to calibration data to infer the current environmental and/or user temperature. A second example mechanism is to analyze the recorded sound to determine properties of the air in a user's ear canal. Because properties of the air such as temperature can affect the playing of sound through that air, the temperature may be deduced by analyzing the recorded sound. This disclosure will next describe each of these temperature-determination mechanism.

First Mechanism: Measure Earpiece Temperature

In the first mechanism, as previously described, the system measures temperature by simultaneously playing and recording audio (audible or inaudible) and detecting changes in the earphone's electrical properties due to temperature changes of the earphone (e.g., its coil). This situation is similar to that of an electrical circuit that contains a resistor whose resistance is temperature-correlated, and where one part of the circuit is connected to a fixed output voltage (e.g., a sound card output), and another part of the circuit is connected to a voltage meter (e.g., a sound card input). With this configuration, one is able to determine the current impulse response of the circuit. The current impulse response can be compared to previously-stored, temperature-dependent impulse responses to determine the current temperature of the resistor. This process is described in detail with respect to certain portions of the process illustrated with respect to process 900 (see FIGS. 9A-D).

At box 902, the computing system determines T by recording a number of audio samples r and determining how temperature affected r given the played audio samples s and known transformation characteristics of the earpiece, such as w₀ and w_(Δ), that affect the played audio signal. Doing so involves use of Equation 1.

At box 904, the operations of box 902 can be performed by using at least a portion of process 600 (see FIG. 6). In particular, the computing system can perform steps 602-624 of process 600 to determine T.

At box 906, the computing system performs a variation of process 600, by solving for T, but adding a high-frequency noise to the output audio signal s. Adding this high-frequency signal to s may be helpful because s may not otherwise include audio at certain times, and because temperature measurement may be more effective with high-frequency signals. Modifying s in this manner can involve performing the process 600 with some variations thereto, which are described below with respect to boxes 908-914.

At box 908, the computing system may set s=s₀+s_(highfreqs). An example high frequency signal may be a 20,000 Hz sine wave.

At box 910, the computing system may perform the operation of box 610, by calculating r_(diff)=r−s*w₀, but with the s value that has been modified to include a high-frequency value, as described above.

At box 912, the computing system may perform the operations of box 612, by calculating r_(Δ)=s_(highfreqs)*w_(Δ). In this example, the operation substitutes s_(highfreqs) instead of s, because s_(highfreqs) may be suitable for calculating temperature (although S=s₀+s_(highfreqs) may be used for other calculations, such as determinations of w_(a)). s_(highfreqs) may not be audible, and thus may not significantly affect w_(a), but still in some examples, s_(highfreqs) is not added to s for determinations of w_(a).

At box 914, the computing system may perform the operations of box 614 by determining the temperature T that minimizes the difference between r_(diff) and the convolution of T and r_(Δ) (i.e., T=argmin_(T)(r_(diff)−T*rΔ)). The values of r_(diff) and r_(Δ), however, may have been influenced by the addition of s_(highfreqs).

At box 916, the computing system may combine multiple values for T over a determined time period. For example, the system may concatenate temperature measurements determined over a time period that is 0.03, 0.05, 0.1, 0.2, or 0.5 seconds long. Example types of combination include averaging and linear regression.

At box 920, the computing system determines the absolute temperature using the proportional temperature T that was determined at box 916. This determination may be performed because the value T may not provide an absolute temperature, but may simply be a voltage value that changes based on temperature, and that can be converted to an absolute temperature (e.g., centigrade) by providing an offset and scaling constant. Since there are multiple temperature described values here, the absolute temperature identified at box 916 will be denoted T_(c), and the relative temperature will be denoted as T_(b). Combining these values into an equation with β to identify an offset and a to represent scaling provides T_(b)=T_(c)α+β.

At box 922, the computing system (or another system) calibrates the values for α and β. This calibration may be performed ahead of time (e.g., before any temperature measurements are taken). For example, the calibration may be performed when a user initially uses a particular earpiece, or can be performed by the manufacturer of the earpiece or by another third-party organization. In these later examples, the calibration values may be shipped with a mobile device or with headphones, or may be accessible through an internet database. There are at last six mechanisms to determine these calibration values, described below with respect to boxes 924-934.

At box 924, in a first mechanism, a user wears the earpiece for a determined amount of time (e.g., 5 or 10 minutes), and the earpiece temperature after that period of time is assumed to be a typical user body temperature. For example, the earpiece temperature may be assumed or estimated to be a mean body temperature of a human (e.g., 36.7 degrees). There may be no measurement of user temperature. Rather, there may be just an assumption that the earpiece is the average human temperature. In some examples, the temperature is estimated to be a typical temperature of an earpiece when placed in an ear of a user with a mean body temperature in a room of a mean room temperature.

At box 926, in a second mechanism, the user wears the earpiece for the determined period of time, and the system asks the user to input temperature T_(c), which may be the user's temperature or the mean temperature of the earpiece and the ambient temperature.

At box 928, in a third mechanism, the earpiece is placed in a room and, after a determined amount of time, the user is asked to input the temperature of the room.

At box 930, in a fourth mechanism, the temperature of the earpiece is measured multiple times at different times of a day and/or on different days. The mean or median temperature measurement in such an example may designated as T_(b) while the mean or median temperature at locations of the mobile device and earpiece at such times according to weather history data may be designated as T_(c).

At box 932, in a fifth mechanism, the earpiece may be placed in a room or other environment, and the system may be connected to an external sensor that determines the absolute temperature T_(c) of the environment in which the earpiece is place, while the earpiece is used to measure its relative temperature T_(b).

At box 934, in a sixth mechanism, a second earpiece may be calibrated based on an already-calibrated first earpiece. First, a first earpiece may be calibrated using any of the above-described mechanisms. Second, the system may then set w_(Δ)=w_(Δ) (alpha) (e.g., by multiplying w_(Δ) by a coefficient and setting it as the new w_(Δ)). Third, some feature of w_(Δ) may be computed and denoted as C (e.g., 2 norm, C=∥w_(Δ)∥ or some weighting on the frequency response of w_(Δ), or some fraction between the response of the earphone in two frequencies). Fourth, a user may connect a second earpiece to a device and the device may compute the same feature of w_(Δ) and denote that feature as D. Fifth, the device may calculate the w_(Δ) of the second earpiece given C, D, and the w_(Δ) of the first earpiece using the following formula: w_(A-second_earpiece)=C/D w_(Δ-first_earpiece). A similar mechanism using w₀ instead of w_(Δ) also applies.

Faster Prediction of Temperature

Sometimes, an earpiece's heat transfer coefficient is small, which means that the earpiece coil and membrane sometimes take a while to reach the temperature of its environment. As an example, in some earpieces, the time constant is around 100 seconds, which means that if the earphone is taken out of a pocket at 30 degrees centigrade and is placed in a 15 degree environment, it could take more than five minutes for the earphone to achieve 15 degrees, plus or minus 0.5 degrees.

At box 940, the computing system identifies the steady-state temperature of the earpiece. This is the temperature that the earpiece may level out at after being in an environment for a certain amount of time. In other words, the earpiece may have the same temperature as its environment at steady state.

At box 942, the computing system may wait a determined amount of time (e.g., 5 minutes in the above example) before designating the temperature of the earpiece as the steady-state earpiece temperature. Essentially, the computing system may wait for the earpiece temperature to heat up or cool down before designating the measured temperature as the steady-state temperature. In some examples, this determination of the amount of time involves the computing system determining when the temperature has stopped changing or that the rate of change in temperature has fallen below a determined threshold.

At box 944, the computing system may use a model of calibrated temperature change over time for the earpiece—along with recent changes in earpiece temperature—to estimate the temperature of the earpiece in the future (e.g., at steady state), even though the earpiece temperature may still be changing and has yet to reach steady state. Using this model may enable estimating the earpiece steady state more quickly than waiting minutes for the earpiece to heat up or cool down. Four such models are described below, with reference to boxes 946 through 952. Because the earpiece may be have a complex body with a coil, plastic, a membrane, and potentially other features, Newton's law of cooling may provide a poor estimation of the earphones temperature in some scenarios, because Newton's law of cooling may best apply to simple materials, such as resistance temperature detectors.

At box 946, as a first example, Newton's law of cooling may be used to determine the future temperature of the transducer, for example, in scenarios in which Newton's law of cooling would provide an adequate estimation of the earphone's temperature. T(t)=T _(env)+(T(t ₀)−T _(env))e ^(−r(t−) ⁰ ⁾

In this equation, e is the temperature at time t, r is the heat transfer coefficient that depends on the type of earpiece, and T_(env) is the temperature of the environment. With the goal of reading temperature samples to estimate T_(env), a system can predict the temperature when r is uncalibrated using the following four steps: (1) Use T₁, T₂, . . . T_(n) at times t₁, t₂, . . . t_(n) as inputs; (2) Use the approximation

${T_{(t)}^{\prime} = \frac{T_{i} - T_{i - 1}}{t_{i} - t_{i - 1}}};$ (3) Use the equation T′^((t))=−r(T_(env)−T(t)) to solve the ML a, b=argmin_(a,b)Σ_(i) (T′_(i)−(a+bT_(i)))²; and (4) set r=b,

${T_{env} = {- \frac{a}{b}}}.$

If r is calibrated, the following two steps may be performed: (1) Use T₁, T₂, . . . T_(n) at times t₁, t₂, . . . t_(n) as inputs; and (2) Solve the MLSQ of the following:

$T_{env} = {\arg\;{\min_{T_{en\nu}}{\sum\limits_{i}\left( {T_{i} - \left( {T_{env} + {\left( {{T\left( t_{0} \right)} - T_{env}} \right)e^{- {r{({t_{i} - t_{0}})}}}}} \right)} \right)^{2}}}}$ This second set of operations may be more quick to perform than the first set of operations because r has already been calibrated. Thus, once r has been calibrated, the system may perform the second set of operations without recalibrating r.

At box 948, as a second example, a General Model may be used to determine the temperature at a time in the future. There exists decreasing functions F₊, F−>0, such that, (F₊, F−→0) If T(t ₀)<T _(env) :T(t+t ₀)=T _(env) −F ₊ ⁻¹(t+F ₊(F+(t ₀)−T _(env))) if T(t ₀)>T _(env) :T(t+t ₀)=T _(env) +F ⁻ ⁻¹(t+F ⁻(F ₊(t ₀)−T _(env))) The functions F₊, F⁻ depend on the earphone's model and material. These equations may be solved using a linear least squares algorithm.

At box 950, as a third example, a General Linear Model may be used to predict the temperature at a time in the future, using a function F: T′(t)=F(T _(env) −T(t))

With this in mind, temperature prediction may be performed using an input of temperature measurements T₁, T₂, . . . T_(n) at times t₁, t₂, . . . t_(n) and a calibrated e. The system can then solve the following optimization problem using enumeration, binary search, or some other method: T _(env)=argmin_(T) _(env) (T′ _(i) −T(t))²

At box 952, as a fourth example, a Sum of Exponents modeling may be used to predict the temperature at a time in the future: T(t)=T _(env)+sum_(i=k)[a _(i) e ^(−r) _(i(t−t) _(o) )]

In this example, the constants a_(i) and r_(i) are coefficients that depend on the earphone's model. This equation may be solved using a linear least squares algorithm.

In some implementations, although the example shown in the figures present calculation of the steady-state temperature after the computing system has converted the relative temperature to an absolute temperature, the system may calculate the steady-state temperature before the temperature is converted from a relative-temperature to an absolute temperature. The conversion may then occur after the calculation of the steady-state temperature.

Body Temperature Measurement (First Approach)

Once the system has measured the temperature of the earpiece (e.g., either by waiting a determined amount of time (see box 942), or using the above-described temperature models to calculate future earpiece temperature (see box 944)), a user ear/body temperature, such as their tympanic temperature may be determined. The earpiece coil may be spaced apart from the user's tympanic membrane, and therefore may have a temperature that is based on a combination of the user's ear temperature and the environmental temperature.

This disclosure describes mechanisms to determine user temperature and even environmental temperature when the temperature of an earpiece is known. In fact, although the following description is explained with reference to a transducer that is used as both a speaker and a microphone, the process would also apply to body and environment temperature determinations that use other types of temperature-sensing devices, such as dedicated microphones, thermometers, resistance temperature detectors, and thermistors. This is because the below discussion explains how to determine a user or environmental temperature sometimes using just the temperature-sensing device (which just happens to be a transducer in this example).

More specifically, and as just mentioned, the temperature of the earpiece (or another temperature-sensing device) depends on the ambient temperature and the temperature of the user's body, such as the ear canal temperature. As such, determination of the body temperature may sometimes involve obtaining multiple temperature measurements over time. Still, the temperature curve that can be constructed from the multiple temperature measurements may be unique for a given ambient/environmental temperature. Accordingly, using the shape of the temperature curve, the system may be able to determine the temperature of the user and the ambient temperature. This process includes four basic steps, which are discussed in turn.

At box 960, the computing system can calibrate the behavior of the temperature curve in multiple ambient temperatures.

At box 962, the computing system can calibrate the ear temperature versus the earpiece temperature in many different ambient temperatures. For example, the system may store, for each of multiple earpiece temperatures, multiple ambient temperatures and the user temperatures that correspond to that specific set of earpiece and ambient temperatures. In other words, the system may store many sets of three temperature, or otherwise use such information to interpolate intermediate values using predictive formulas.

Both these calibrating steps may be performed ahead of time, for example, before any real-time temperature measurement is taken. Indeed, the calibration may occur at a factory and be pre-installed with the earpiece or mobile device, or may be accessible through an internet database.

At box 964, the computing system may record multiple earpiece temperature measurements.

At box 966, the computing system can use the multiple earpiece temperature measurements and the calibration information identified at box 960 to determine the ambient temperature.

At box 968, the computing system can use one or more of the multiple earpiece temperature measurements and the calibration information identified with respect to box 962 to determine the user temperature. For example, the system may identify the user temperature that matches the determined earpiece temperature and the determined ambient temperature.

There are at least two models that can be used to calculate the ambient and user temperatures given a series of temperature measurements and calibrated values.

The first such model is a general model. There exist decreasing functions F₊, F⁻, G, G₊>0, such that (F₊, F⁻, G⁻, G₊→0) if T (t₀)<αT_(ear)+(1−α)T_(amb) The functions F+, F− depend on various characteristics, such as the earpiece model, material, and design. T(t+t ₀)=αT _(ear)(1−α)T _(amb) −F ₊(t+F ₊ ⁻¹(F ₊(t ₀)−T _(ear)))−G ₊(t+G ₊ ⁻¹(G ₊(t ₀)−T _(amb))) if T(t ₀)<αT _(ear)+(1−α)T _(amb) ,T(t+t ₀)<αT _(ear)(1−α)T _(amb) +F ⁻(t+F ⁻ ⁻¹(F−(t ₀)−T _(ear)))+G ⁻(t+G ⁻(G ⁻ ⁻¹(t ₀)−T _(amp))) To solve for the general model, the system can first calibrate for F and G for various values of ambient temperature and a. Then, a system may deduce T_(amb) and T_(ear) using MLSQ.

The second such model is Newton's model. T(t)=P[T _(amb) ,T _(ear)]+(T(t ₀)−T _(env))e ^(−R[T) ^(amb) ^(](t−t) ⁰ ⁾ Sometimes, P[T _(amb) ,T _(ear)]=αT _(amb)+(1−α)T _(ear), and then T(t)=αT _(amb)+(1−α)T _(ear)]+(T(t ₀)−T _(env))e ^(−R[T) ^(amb) ^(](t−t) ⁰ ⁾ In this example, P(T_(amb), T_(ear)) is the final temperature of the earpiece when the ambient temperature is T_(amb) and the eardrum temperature is T_(env). R[T_(amb)] is a function using the ambient temperature. In this model, the heat coefficient may depend on the ambient temperature. To solve for Newton's model the system may perform five steps. First, the system may calibrate R(T_(amb)) for some values of ambient temperature, and P. Second, the system may interpolate R(T_(amb)) (e.g., by plotting a straight line between at least two points to enable estimating points in between or to the sides of the two points). Third, the system may deduce r by continuously recording the earpiece temperature. Fourth, the system may find T_(amb), such that R(T_(amb))=r, since T_(amb) may be known, and T_(inferred) may be measured (either by waiting some time, or using the above-described time-prediction techniques). Fifth, using the above-described equation, T_(ear) may be determined by solving the following equation for T_(ear), since P may be known, T_(amb) may be known, and T_(inferred) may be known (using prediction): T_(inferred)=P(T_(amb), T_(amb)) Body Temperature Measurement (Second Approach)

In this alternative approach, the computing system calculates the earpiece temperature as described previously, but the earpiece temperature is designated as the ambient temperature due to the earpiece being determined to be located outside of the user's ear and thus influenced primarily by the ambient temperature. (The in-ear-detection technique described with respect to process 700 is used to identify when the earpiece is outside of the ear.) Once the ear piece is determined to be in the ear, the system may be able to determine the user temperature since the ambient temperature is known and the earpiece temperature is known, and the system may have access to previously-performed calibrations that map ear temperature to earpiece temperature for various ambient temperatures. This process is described in more detail with respect to boxes 980-986.

At box 980, the computing system determines whether the earpiece is in the user's ear, for example, using the in-ear-detection process 700. The computing system may regularly perform this process, until the system determines that the earpiece is not in the user's ear, at which point the computing system may perform the operations of box 982 to effectively begin the temperature-measurement process.

At box 982, the computing system may determine the absolute steady-state earpiece temperature, and designate this temperature as the ambient temperature. The determination of the absolute steady-state earpiece temperature may involve performing the operations of boxes 900-940 to calculate the steady-state temperature of the earpiece. In this case, since the earpiece is not in a user's ear, it can be assumed that the earpiece is the same or at least similar to the ambient temperature of the space in which the earpiece is located. As described with respect to box 940, determining the steady-state temperature can involve waiting a determined length of time until the earpiece reaches the ambient temperature (box 942), or can involve using a model to calculate the future steady-state temperature (box 944).

At box 984, the computing system determines whether the earpiece is in the user's ear, for example, using the in-ear-detection process 700. If the earpiece is not determined to be in the user's ear, the system continues determining the absolute steady-state earpiece temperature (box 982). If the system determines that the earpiece is now located in the user's ear, the computing system performs the operations of box 966. In various examples, the computing system continues to record the earpiece temperatures and does not perform the operations of box 982 to determine the steady-state earpiece temperature until the computing system has determined whether the earpiece has transitioned to being in a user's ear. Waiting to determine the ambient temperature allows the computing system to select between simply using the last temperature reading (e.g., because the earpiece has reached steady-state environmental temperature) or using temperature modeling (e.g., because the earpiece temperature was still changing).

At box 986, the computing system calibrates ear temperature versus earpiece temperature for multiple ambient temperatures (e.g., ear temperature versus ambient temperature for multiple earpiece temperatures), as described previously with respect to box 962.

At box 990, the computing system determines the ear temperature using the absolute steady-state earpiece temperature, the determined ambient temperature, and the data that calibrated ear to earpiece to ambient temperatures. For example, the computing system may identify an earpiece temperature from the calibrated data that matches the determined earpiece temperature, then from among multiple ambient temperatures stored for that earpiece temperature, select the ambient temperature that matches the stored ambient temperature, and with these two values already selected, select the corresponding ear temperature from the data set. In some examples, the calibrated data uses interpolation or a similar process where the recorded values are not identical to the calibrated data.

Second Mechanism: Measure Characteristics of Environment

As the temperature changes, the acoustic characteristics of an environment in which the earpiece is located may change. For example, temperature can affect the speed of sound in an environment, as well as the amplitude and other characteristics. As such, the acoustic echo r_(a) and acoustic response w_(a), which are affected by sound speed and amplitude, may change as the temperature changes. Accordingly, comparing either the acoustic echo r_(a) or acoustic response w_(a) to corresponding values that are calibrated for different temperatures, can allow a system to determine the temperature inside a user's ear. This process is described below with respect to process 1000 (FIG. 10) and boxes 1002 through 1008.

At box 1002, the computing system extracts the acoustic echo r_(a) or the acoustic response w_(a) while audio is being played, as described previously with respect to process 600.

At box 1004, the computing system accesses a set of pre-calibrated acoustic echoes or responses, where there is at least one pre-calibrated value for each temperature value.

At box 1006, the computing system compares the extracted acoustic echo r_(a) or the acoustic response w_(a) to a pre-calibrated acoustic echo or response P_(a) that was calibrated for an estimated temperature, designated here as X degrees Celsius.

At box 1008, the computing system uses a feature from the extracted acoustic echo r_(a) or the acoustic response w_(a) and compares that feature to a same feature of the pre-calibrated acoustic echo or response P_(a), to identify a matching ear canal temperature. As a first example, the system may extract the time difference between the played and recorded signal, which may be temperature correlated according to the effect of temperature on the speed of sound. As a second example, the system may compare the amplitude of the recorded signal to the amplitude of the played signal. As another example, the system may find the entire impulse response between the played and recorded signal, compare it to the impulse response at X degrees, and use a model of contraction due to the speed of sound. Such mechanisms may be used to determine a relative temperature of the ear.

At box 1010, the computing system converts the determined relative temperature of the ear to an absolute temperature of the ear, for example, by performing the operations of box 920.

FIG. 11 is a schematic diagram of a computer system 1100. The system 1100 can be used to carry out the operations described in association with any of the computer-implemented methods described previously, according to one implementation. The system 1100 is intended to include various forms of digital computers, such as laptops, desktops, workstations, personal digital assistants, servers, blade servers, mainframes, and other appropriate computers. The system 1100 can also include mobile devices, such as personal digital assistants, cellular telephones, smartphones, and other similar computing devices. Additionally the system can include portable storage media, such as, Universal Serial Bus (USB) flash drives. For example, the USB flash drives may store operating systems and other applications. The USB flash drives can include input/output components, such as a wireless transmitter or USB connector that may be inserted into a USB port of another computing device.

The system 1100 includes a processor 1110, a memory 1120, a storage device 1130, and an input/output device 1140. Each of the components 1110, 1120, 1130, and 1140 are interconnected using a system bus 1150. The processor 1110 is capable of processing instructions for execution within the system 1100. The processor may be designed using any of a number of architectures. For example, the processor 1110 may be a CISC (Complex Instruction Set Computers) processor, a RISC (Reduced Instruction Set Computer) processor, or a MISC (Minimal Instruction Set Computer) processor.

In one implementation, the processor 1110 is a single-threaded processor. In another implementation, the processor 1110 is a multi-threaded processor. The processor 1110 is capable of processing instructions stored in the memory 1120 or on the storage device 1130 to display graphical information for a user interface on the input/output device 1140.

The memory 1120 stores information within the system 1100. In one implementation, the memory 1120 is a computer-readable medium. In one implementation, the memory 1120 is a volatile memory unit. In another implementation, the memory 1120 is a non-volatile memory unit.

The storage device 1130 is capable of providing mass storage for the system 400. In one implementation, the storage device 1130 is a computer-readable medium. In various different implementations, the storage device 1130 may be a floppy disk device, a hard disk device, an optical disk device, or a tape device.

The input/output device 1140 provides input/output operations for the system 400. In one implementation, the input/output device 1140 includes a keyboard and/or pointing device. In another implementation, the input/output device 1140 includes a display unit for displaying graphical user interfaces.

The features described can be implemented in digital electronic circuitry, or in computer hardware, firmware, software, or in combinations of them. The apparatus can be implemented in a computer program product tangibly embodied in an information carrier, e.g., in a machine-readable storage device for execution by a programmable processor; and method steps can be performed by a programmable processor executing a program of instructions to perform functions of the described implementations by operating on input data and generating output. The described features can be implemented advantageously in one or more computer programs that are executable on a programmable system including at least one programmable processor coupled to receive data and instructions from, and to transmit data and instructions to, a data storage system, at least one input device, and at least one output device. A computer program is a set of instructions that can be used, directly or indirectly, in a computer to perform a certain activity or bring about a certain result. A computer program can be written in any form of programming language, including compiled or interpreted languages, and it can be deployed in any form, including as a stand-alone program or as a module, component, subroutine, or other unit suitable for use in a computing environment.

Suitable processors for the execution of a program of instructions include, by way of example, both general and special purpose microprocessors, and the sole processor or one of multiple processors of any kind of computer. Generally, a processor will receive instructions and data from a read-only memory or a random access memory or both. The essential elements of a computer are a processor for executing instructions and one or more memories for storing instructions and data. Generally, a computer will also include, or be operatively coupled to communicate with, one or more mass storage devices for storing data files; such devices include magnetic disks, such as internal hard disks and removable disks; magneto-optical disks; and optical disks. Storage devices suitable for tangibly embodying computer program instructions and data include all forms of non-volatile memory, including by way of example semiconductor memory devices, such as EPROM, EEPROM, and flash memory devices; magnetic disks such as internal hard disks and removable disks; magneto-optical disks; and CD-ROM and DVD-ROM disks. The processor and the memory can be supplemented by, or incorporated in, ASICs (application-specific integrated circuits).

To provide for interaction with a user, the features can be implemented on a computer having a display device such as a CRT (cathode ray tube) or LCD (liquid crystal display) monitor for displaying information to the user and a keyboard and a pointing device such as a mouse or a trackball by which the user can provide input to the computer. Additionally, such activities can be implemented via touchscreen flat-panel displays and other appropriate mechanisms.

The features can be implemented in a computer system that includes a back-end component, such as a data server, or that includes a middleware component, such as an application server or an Internet server, or that includes a front-end component, such as a client computer having a graphical user interface or an Internet browser, or any combination of them. The components of the system can be connected by any form or medium of digital data communication such as a communication network. Examples of communication networks include a local area network (“LAN”), a wide area network (“WAN”), peer-to-peer networks (having ad-hoc or static members), grid computing infrastructures, and the Internet.

The computer system can include clients and servers. A client and server are generally remote from each other and typically interact through a network, such as the described one. The relationship of client and server arises by virtue of computer programs running on the respective computers and having a client-server relationship to each other.

While this specification contains many specific implementation details, these should not be construed as limitations on the scope of any inventions or of what may be claimed, but rather as descriptions of features specific to particular implementations of particular inventions. Certain features that are described in this specification in the context of separate implementations can also be implemented in combination in a single implementation. Conversely, various features that are described in the context of a single implementation can also be implemented in multiple implementations separately or in any suitable subcombination. Moreover, although features may be described above as acting in certain combinations and even initially claimed as such, one or more features from a claimed combination can in some cases be excised from the combination, and the claimed combination may be directed to a subcombination or variation of a subcombination.

Similarly, while operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results. In certain circumstances, multitasking and parallel processing may be advantageous. Moreover, the separation of various system components in the implementations described above should not be understood as requiring such separation in all implementations, and it should be understood that the described program components and systems can generally be integrated together in a single software product or packaged into multiple software products.

Thus, particular implementations of the subject matter have been described. Other implementations are within the scope of the following claims. In some cases, the actions recited in the claims can be performed in a different order and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In certain implementations, multitasking and parallel processing may be advantageous.

Pre-Recorded Sounds

Implementation 1 is a computer-implemented method. The method includes playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece. The method further includes recording, with the audio processing device and while playing the source audio signal, an ambient audio signal that indicates sounds present within an environment of the user. The method further includes identifying, based on analysis of the ambient audio signal, that a pre-recorded audio signal occurs in the ambient audio signal. The method further includes accessing a second instance of the pre-recorded audio signal. The method further includes modifying, with the audio processing device and using the stored instance of the pre-recorded audio signal as a representation of the pre-recorded audio signal that occurs in the ambient audio signal, the source audio signal output by the electroacoustic transducer of the user earpiece so as to at least partially remove the pre-recorded audio signal from the source audio signal.

Implementation 2 is the method of implementation 1. The source audio signal comprises an audio signal from at least one of a song or spoken content.

Implementation 3 is the method of implementation 1. The pre-recorded audio signal comprises an audio signal from at least one of a song, spoken content, a movie, or a television show.

Implementation 4 is the method of implementation 1. Identifying that the pre-recorded audio signal occurs in the ambient audio signal comprises: filtering, with the audio processing device, the ambient audio signal to extract the pre-recorded audio signal from the ambient audio signal; and determining that the pre-recorded audio signal extracted from the ambient audio signal matches one of a plurality of different pre-recorded audio signals.

Implementation 5 is the method of implementation 1. Identifying that the pre-recorded audio signal occurs in the ambient audio signal comprises: sending, from the audio processing device and over a network to a server remotely located from the audio processing device, audio data that characterizes at least a portion of the ambient audio signal; and receiving, at the audio processing device as a response to the audio data sent to the server, data that identifies the pre-recorded audio signal.

Implementation 6 is the method of implementation 5. Accessing the stored instance of the pre-recorded audio signal comprises receiving, at the audio processing device as part of the response to the audio data sent to the server, the second instance of the pre-recorded audio signal.

Implementation 7 is the method of any one of implementations 1-6. The method includes determining a current temporal position of the pre-recorded audio signal that occurs in the ambient audio signal; and synchronizing the second instance of the pre-recorded audio signal with the pre-recorded audio signal that occurs in the ambient audio signal based on the determined current temporal position.

Implementation 8 is the method of implementation 7. Modifying the source audio signal so as to at least partially remove the pre-recorded audio signal from the source audio signal comprises filtering the source audio signal in real-time with the synchronized second instance of the pre-recorded audio signal.

Implementation 9 is the method of any one of implementations 1-8. The method comprises identifying that the pre-recorded audio signal no longer occurs in the ambient audio signal; and in response to identifying that the pre-recorded audio signal no longer occurs in the ambient audio signal, ceasing modification of the source audio signal so as to at least partially remove the pre-recorded audio signal from the source audio signal.

Implementation 10 is the method of implementation 9. The method comprises after ceasing modification of the source audio signal: identifying that the pre-recorded audio signal has resumed in the ambient audio signal; and in response to identifying that the pre-recorded audio signal has resumed in the ambient audio signal, resuming modification of the source audio signal so as to at least partially remove the pre-recorded audio signal from the source audio signal.

Implementation 11 is the method of any one of implementations 1-10. Recording the ambient audio signal comprises sensing the ambient audio signal with the electroacoustic transducer of the user earpiece.

Implementation 12 is the method of any one of implementations 1-10. Recording the ambient audio signal comprises sensing the ambient audio signal with a microphone that is external to the user earpiece.

Implementation 13 is the method of implementation 12. The microphone is further external to the audio processing device

Implementation 14 is the method of implementation 12. The microphone is an integrated component of the audio processing device.

Implementation 15 is the method of any one of implementations 1-14. Modifying the source audio signal output by the electroacoustic transducer of the user earpiece comprises subtracting the second instance of the pre-recorded audio signal from the source audio signal

Implementation 16 is the method of any one of implementations 1-15. The earpiece comprises a headphone or an earbud.

Implementation 17 is the method of any one of implementations 1-16. The audio processing device comprises a portable digital media player, a smartphone, a tablet computing device, a notebook computing device, a desktop computing device, or a wearable computing device.

Implementation 18 is a computing system. The computing system includes one or more processors and one or more computer-readable media. The one or more computer-readable media have instructions stored thereon that, when executed by the one or more processors, cause performance of operations that carry out any of the methods of implementations 1-17.

Implementation 19 is one or more computer-readable media that have instructions stored thereon that, when executed by one or more processors, cause performance of operations that carry out any of the methods of implementations 1-17.

Ear Presence

Implementation 1 is a computer-implemented method. The method includes playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece; recording, with the audio processing device, an aural signal using the electroacoustic transducer of the user earpiece; determining values of one or more features of the aural signal that indicate, as a result of playing the source audio signal, a characteristic of a space in which the user earpiece is located; comparing the determined values of the one or more features of the aural signal with pre-defined values of the one or more features; and based on a result of comparing the determined values of the one or more features of the aural signal with the pre-defined values of the one or more features, determining whether the user earpiece is located at a user's ear.

Implementation 2 is the method of implementation 1. The method comprises determining whether to perform a specified action based on whether the user earpiece is located at the user's ear.

Implementation 3 is the method of implementation 1. The method comprises determining, at a first time, that the user earpiece is located at the user's ear; determining, at a second time after the first time, that the location of the user earpiece is changed from being at the user's ear to not being at the user's ear; and in response to determining that the location of the user earpiece is changed from being at the user's ear to not being at the user's ear, performing a specified action.

Implementation 4 is the method of implementation 1. The method comprises determining, at a first time, that the user earpiece is not located at the user's ear; determining, at a second time after the first time, that the location of the user earpiece is changed from being not at the user's ear to being at the user's ear; and in response to determining that the location of the user earpiece is changed from being not at the user's ear to being at the user's ear, performing a specified action.

Implementation 5 is the method of any one of implementations 2-4. The specified action comprises at least one of playing a media file, pausing the media file, stopping the media file, resuming play of a paused media file, activating an electronic display, adjusting a brightness setting of a backlight of the electronic display, transitioning a device into a locked mode, transitioning a device out of a locked mode, initiating a telephone call, ending a telephone call, launching an application, or closing an application.

Implementation 6 is the method of any one of implementations 1-5. The method comprises repeatedly determining whether the user earpiece is located at the user's ear over a period of time to monitor for a change in location of the user earpiece from (i) not being at the user's ear to being at the user's ear or (ii) from being at the user's ear to not being at the user's ear.

Implementation 7 is the method of any one of implementations 1-6. The method comprises recording the aural signal with the audio processing device concurrently with playing the source audio signal with the audio processing device.

Implementation 8 is the method of any one of implementation 1-6. The electroacoustic transducer of the user earpiece concurrently functions as (i) a speaker that audibly outputs the source audio signal and (ii) a microphone that senses the aural signal while the source audio signal is played.

Implementation 9 is the method of any one of implementations 1-8. The one or more features of the aural signal comprise an impulse response of an acoustic echo of the space in which the user earpiece is located.

Implementation 10 is the method of any one of implementations 1-9. The pre-defined values of the one or more features comprise a model that characterizes a space in the user's ear.

Implementation 11 is the method of any one of implementations 1-10. The pre-defined values of the one or more features are determined based at least in part on previously determined values of the one or more features of aural signals that resulted from playing the source audio signal or another audio signal when the user earpiece was determined to be located at the user's ear.

Implementation 12 is the method of any one of implementations 1-10. The pre-defined values of the one or more features are determined based at least in part on values of the one or more features of aural signals that resulted from playing the source audio signal or another audio signal when the user earpiece was located at the respective ears of one or more users other than the user.

Implementation 13 is the method of any one of implementations 1-12. The earpiece comprises a headphone or an earbud.

Implementation 14 is the method of any one of implementations 1-13. The audio processing device comprises a portable digital media player, a smartphone, a tablet computing device, a notebook computing device, a desktop computing device, or a wearable computing device.

Implementation 15 is the method of any one of implementations 1-14. Playing the source audio signal comprises playing white noise.

Implementation 16 is the method of any one of implementations 1-14. Playing the source audio signal comprises playing a song or spoken content to the user of the audio processing device.

Implementation 17 is the method of any one of implementations 1-16. Playing the source audio signal comprises playing sound having an average frequency that is greater than 20 kiloHertz, such that the played sound is above a normal frequency limit for human hearing.

Implementation 18 is a computing system. The computing system includes one or more processors and one or more computer-readable media. The one or more computer-readable media have instructions stored thereon that, when executed by the one or more processors, cause performance of operations that carry out any of the methods of implementations 1-17.

Implementation 19 is one or more computer-readable media that have instructions stored thereon that, when executed by one or more processors, cause performance of operations that carry out any of the methods of implementations 1-17.

User Authentication

Implementation 1 is a computer-implemented method. The method includes playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece. The method further includes recording, with the audio processing device, an aural signal that is sensed by the electroacoustic transducer of the user earpiece. The method further includes determining values of one or more features of the aural signal that indicate, as a result of playing the source audio signal, a characteristic of a space in which the user earpiece is located. The method further includes generating an acoustic signature for the user based on the values of the one or more features of the aural signal. The method further includes registering the acoustic signature with a user account.

Implementation 2 is the method of implementation 1. The method further includes comprising after registering the acoustic signature with the user account: playing, with the audio processing device, a second source audio signal, including causing the second source audio signal to be audibly output by the electroacoustic transducer of the user earpiece; recording, with the audio processing device, a second aural signal that is sensed by the electroacoustic transducer of the user earpiece; determining values of the one or more features of the second aural signal; determining whether the one or more features of the second aural signal match the acoustic signature that is registered with the user account; and determining, based on whether the one or more features of the second aural signal match the acoustic signature that is registered with the user account, whether to perform a specified action.

Implementation 3 is the method of implementation 2. Determining whether to perform the specified action comprises authenticating a user of the user earpiece based on whether the one or more features of the second aural signal match the acoustic signature that is registered with the user account.

Implementation 4 is the method of implementation 2. The specified action comprises logging into the user account or another account.

Implementation 5 is the method of implementation 2. The method includes determining that the one or more features of the second aural signal match the acoustic signature that is registered with the user account; and in response to determining that the one or more features of the second aural signal match the acoustic signature that is registered with the user account, permitting performance of the specified action.

Implementation 6 is the method of implementation 2. The method includes determining that the one or more features of the second aural signal do not match the acoustic signature that is registered with the user account; and in response to determining that the one or more features of the second aural signal do not match the acoustic signature that is registered with the user account, blocking performance of the specified action.

Implementation 7 is the method of implementation 2. The method includes repeatedly determining values of the one or more features of the second aural signal while the audio processing device is in a first mode associated with the specified action; determining to remain in the first mode of the audio processing device associated with the specified action so long as the values of the one or more features of the second aural signal determined in iterations of the repeatedly determining match the acoustic signature that is registered with the user account.

Implementation 8 is the method of implementation 7. The method further includes determining to transition from the first mode associated with the specified action to a second mode associated with the specified action in response to determining that the values of the one or more features of the second aural signal no longer match the acoustic signature that is registered with the user account.

Implementation 9 is the method of implementation 7. The first mode associated with the specified action comprises being logged into a restricted user account.

Implementation 10 is the method of implementation 8. The first mode associated with the specified action comprises being logged into a restricted user account, wherein the second mode associated with the specified action comprises being logged out of the restricted user account.

Implementation 11 is the method of any one of implementations 1-10. The method comprises correlating the acoustic signature with a first position of the user earpiece at the user's ear.

Implementation 12 is the method of any one of implementations 1-11. The method comprises performing multiple iterations of the steps of playing, recording, determining, and generating so as to generate multiple acoustic signatures for the user; prompting the user to move the user earpiece to a different position at the user's ear for each iteration of the multiple iterations; and correlating at least two of the multiple acoustic signatures for the user with at least two different positions of the user earpiece at the user's ear.

Implementation 13 is the method of any one of implementations 1-12. The method includes recording the aural signal with the audio processing device concurrently with playing the source audio signal with the audio processing device.

Implementation 14 is the method of any one of implementations 1-13. The electroacoustic transducer of the user earpiece concurrently functions as (i) a speaker that audibly outputs the source audio signal and (ii) a microphone that senses the aural signal while the source audio signal is played.

Implementation 15 is the method of any one of implementations 1-14. The one or more features of the aural signal comprise an impulse response of an acoustic echo of the space in which the user earpiece is located.

Implementation 16 is the method of any one of implementations 1-15. The pre-defined values of the one or more features comprise a model that characterizes a space in the user's ear.

Implementation 17 is the method of any one of implementations 1-16. The user earpiece comprises a headphone or an earbud.

Implementation 18 is the method of any one of implementations 1-17. Playing the source audio signal comprises playing white noise.

Implementation 19 is the method of any one of implementations 1-17. Playing the source audio signal comprises playing a song or spoken content to the user of the audio processing device.

Implementation 20 is the method of any one of implementations 1-17. Playing the source audio signal comprises playing sound having an average frequency that is greater than 20 kiloHertz, such that the played sound is above a normal frequency limit for human hearing.

Implementation 21 is a computing system. The computing system includes one or more processors and one or more computer-readable media. The one or more computer-readable media have instructions stored thereon that, when executed by the one or more processors, cause performance of operations that carry out the methods of implementations 1-20.

Implementation 22 is one or more computer-readable media having instructions stored thereon that, when executed by one or more processors, cause performance of operations that carry out the methods of any of implementations 1-20.

Using Acoustic Signatures

Implementation 1 is a computer-implemented method. The method includes playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece. The method further includes recording, with the audio processing device, an aural signal that is sensed by the electroacoustic transducer of the user earpiece. The method further includes determining values of one or more features of the aural signal that indicate, as a result of playing the source audio signal, a characteristic of a space in which the user earpiece is located. The method further includes determining whether the one or more features of the aural signal match one or more acoustic signatures that are registered with a user account. The method further includes determining, based on whether the one or more features of the aural signal match the one or more acoustic signatures that are registered with the user account, whether to perform a specified action.

Implementation 2 is a computing system. The computing system includes one or more processors and one or more computer-readable media. The one or more computer-readable media have instructions stored thereon that, when executed by the one or more processors, cause performance of operations that carry out the method of implementation 1.

Implementation 3 is one or more computer-readable media having instructions stored thereon that, when executed by one or more processors, cause performance of operations that carry out the method of implementation 1.

Configuring Simultaneous Playing and Recording

Implementation 1 is a system to simultaneously play and record audio using a same transducer. The system includes an audio processing circuit that

includes an audio output connection, an audio input connection, and a ground connection. The system includes a transducer that includes a first electrical connection and a second electrical connection. The system includes a resistor that is connected between the audio output connection of the audio processing circuit and the audio input connection of the audio processing circuit. The system includes a first electrical conductor between the first electrical connection of the transducer and either the audio output connection of the audio processing circuit or the audio input connection of the audio processing circuit. The system includes a second electrical conductor between the second electrical connection of the transducer and the ground connection of the audio processing circuit. Implementation 2 is the system of implementation 1, wherein the first electrical conductor is a wire, and the second electrical conductor is a wire.

Implementation 3 is the system of implementation 1, wherein: a resistance between the first electrical connection of the transducer and the audio output connection of the audio processing circuit is less than 1 ohm, or the resistance between the first electrical connection of the transducer and the audio input connection of the audio processing circuit is less than 1 ohm.

Implementation 4 is the system of implementation 1, wherein the resistor has a resistance greater than 5 ohms.

Implementation 5 is the system of implementation 1, wherein the resistor has a resistance greater than 50 ohms.

Implementation 6 is the system of implementation 1, further comprising a first circuit element that is configured to switch the resistor that is connected between the audio output connection and the audio input connection so that the resistor is no longer connected between the audio output connection and the audio input connection.

Implementation 7 is the system of implementation 6, comprising the first circuit element or a second circuit element that is configured to connect the first electrical connection of the transducer to the audio output connection of the transducer or the audio input connection of the transducer as a result of the resistor being switched so that it is no longer connected between the audio output connection and the audio input connection.

Implementation 8 is the system of implementation 1, wherein the first electrical conductor is connected between the first electrical connection of the transducer and the audio input connection of the audio processing circuit

Implementation 9 is the system of implementation 1, wherein the audio input connection includes a first input connection that is connected to a first side of the resistor and a second input connection that is connected to a second side of the resistor, such that the first input connection and the second input connection are connected across the resistor.

Temperature Measurement Mechanism

Implementation 1 is a computer-implemented method. The method comprises playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece. The method comprises recording, with the audio processing device and while playing the source audio signal, a recorded audio signal using the electroacoustic transducer of the user earpiece. The method comprises identifying, by the audio processing device, one or more parameters that indicate how properties of the user earpiece affect playing of the source audio signal by the electroacoustic transducer, wherein at least one of the one or more parameters is temperature dependent. The method comprises determining, by the audio processing device, a temperature value that is estimated to cause the source audio signal that was played by the audio processing device to result in the recorded audio signal, accounting for changes to the source audio signal that occur due to application of the one or more parameters.

Implementation 2 is the computer-implemented method of implementation 1, wherein the at least one of the one or more parameters is a temperature-dependent impulse response of the user earpiece.

Implementation 3 is the computer-implemented method of implementation 1, wherein the at least one of the one or more parameters is a temperature-dependent frequency response of the user earpiece.

Implementation 4 is the computer-implemented method of implementation 1, wherein the temperature value represents a relative temperature value of the transducer. The method further comprises modifying the temperature value using an offset constant and a scaling constant to generate an absolute temperature value of the user earpiece, wherein the offset constant and the scaling constant are values that were calibrated for the user earpiece or a type of the user earpiece.

Implementation 5 is the computer-implemented method of implementation 1, wherein the temperature value represents a temperature value of the transducer. The method further comprises estimating, using the determined temperature value, an environmental temperature value of an environment in which the user earpiece is located by identifying a temperature of the user earpiece at a future time using a model that represents earpiece temperature-change characteristics over time.

Implementation 6 is the computer-implemented method of implementation 1, wherein the temperature value represents a temperature value of the transducer. The method further comprises estimating, using the determined temperature value and an environmental temperature value of an environment in which the user earpiece is located, a user body temperature value of a user body to which the user earpiece is adjacent and touching by correlating the user body temperature value to previously-calibrated sets of user body temperature, user earpiece temperature, and environmental temperature that correlate to each other.

Implementation 7 is the computer-implemented method of implementation 1. The method further comprises determining, by the audio processing device, that the user earpiece is not located in a user ear, wherein the playing of the source audio signal and the recording of the recorded audio signal occur while the audio processing device has determined that the user earpiece is not located in the user ear, such that the determined temperature value is designated as an environmental temperature value.

Implementation 8 is the computer-implemented method of implementation 7. The method further comprises determining, by the audio processing device and after the user earpiece has been determined to not be located in the user ear, that the user earpiece is now located in a user ear, and in response: (i) playing, with the audio processing device, a second source audio signal using the electroacoustic transducer, (ii) recording, with the audio processing device and while playing the second source audio signal, a second recorded audio signal, and (iii) determining, by the audio processing device, a second temperature value that is estimated to cause the second source audio signal that was played by the audio processing device to result in the second recorded audio signal, accounting for changes to the second source audio signal that occur due to application of one or more parameters, wherein the second temperature value differs from the determined temperature value that is designated as the environmental temperature value because temperature of the earpiece has changed after the earpiece was placed in the user ear. The method further comprises estimating, by the audio processing device, a user body temperature value using the determined temperature value that is designated as the environmental temperature value and the second temperature value.

Implementation 9 is the computer-implemented method of implementation 8, wherein estimating the user body temperature using the determined temperature value and the second temperature value includes correlating the user body temperature to previously-calibrated sets of user body temperature, user earpiece temperature, and environmental temperature that correlate to each other.

Implementation 10 is a computing system comprising: one or more processors; and one or more computer-readable media having instructions stored thereon that, when executed by the one or more processors, cause performance of operations that carry out any of the method of claims 1-9.

Implementation 11 is one or more computer-readable media having instructions stored thereon that, when executed by one or more processors, cause performance of operations that carry out any of the methods of claims 1-9.

Another Temperature Measurement Mechanism

Implementation 1 is a computer-implemented method. The method comprises playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece. The method comprises recording, with the audio processing device and while playing the source audio signal, a recorded audio signal using the electroacoustic transducer of the user earpiece. The method comprises identifying, by the audio processing device, one or more parameters that indicate how properties of the earpiece affect playing of the source audio signal by the electroacoustic transducer. The method comprises determining, by the audio processing device, a parameter that indicates how properties of the user ear environment at which the user earpiece is located affects the source audio signal that was played by the audio processing device, accounting for changes to the source audio signal that occur due to application of the one or more parameters that indicate how properties of the earpiece affect playing of the source audio signal. The method comprises using, by the audio processing device, the parameter that indicates how the properties of the user ear affects the source audio signal to determine a temperature value.

Implementation 2 is the computer-implemented method of implementation 1, wherein the temperature value represents a relative temperature value of the user ear environment. The method further comprises modifying the temperature value using an offset constant and a scaling constant to generate an absolute temperature value of the user ear environment, wherein the offset constant and the scaling constant are values that were calibrated for the user earpiece or a type of the user earpiece.

Implementation 3 is a computing system comprising one or more processors; and one or more computer-readable media having instructions stored thereon that, when executed by the one or more processors, cause performance of operations that carry out any of the method of implementations 1-2.

Implementation 4 is one or more computer-readable media having instructions stored thereon that, when executed by one or more processors, cause performance of operations that carry out any of the methods of implementations 1-2.

In some implementations, the audio processing device may be configured to perform various combinations of the techniques described herein, including two or more of the in-ear detection techniques, active-noise cancellation with pre-recorded sounds techniques, and aural-based authentication techniques.

In some implementations, the techniques described herein may be performed using wireless earpieces that are communicably coupled with a computing device via a wireless connection (e.g., BLUETOOTH). For example, the wireless earpieces may digitally sample recorded sounds and either process the sounds locally at the headset or transmit the recorded signal to a separate audio processing device to perform, e.g., aural-based authentication, in-ear detection, and/or active-noise cancellation with pre-recorded sounds. 

What is claimed is:
 1. A computer-implemented method, comprising: playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece; recording, with the audio processing device and while playing the source audio signal, a recorded audio signal using the electroacoustic transducer of the user earpiece; identifying, by the audio processing device, one or more parameters that indicate how properties of the user earpiece affect playing of the source audio signal by the electroacoustic transducer, wherein at least one of the one or more parameters is temperature dependent; and determining, by the audio processing device, a temperature value that is estimated to cause the source audio signal that was played by the audio processing device to result in the recorded audio signal, accounting for changes to the source audio signal that occur due to application of the one or more parameters.
 2. The computer-implemented method of claim 1, wherein the at least one of the one or more parameters is a temperature-dependent impulse response of the user earpiece.
 3. The computer-implemented method of claim 1, wherein the at least one of the one or more parameters is a temperature-dependent frequency response of the user earpiece.
 4. The computer-implemented method of claim 1, wherein the temperature value represents a relative temperature value of the transducer, wherein the method further comprises modifying the temperature value using an offset constant and a scaling constant to generate an absolute temperature value of the user earpiece, wherein the offset constant and the scaling constant are values that were calibrated for the user earpiece or a type of the user earpiece.
 5. The computer-implemented method of claim 1, wherein the temperature value represents a temperature value of the transducer, wherein the method further comprises estimating, using the determined temperature value, an environmental temperature value of an environment in which the user earpiece is located by identifying a temperature of the user earpiece at a future time using a model that represents earpiece temperature-change characteristics over time.
 6. The computer-implemented method of claim 1, wherein the temperature value represents a temperature value of the transducer, wherein the method further comprises estimating, using the determined temperature value and an environmental temperature value of an environment in which the user earpiece is located, a user body temperature value of a user body to which the user earpiece is adjacent and touching by correlating the user body temperature value to previously-calibrated sets of user body temperature, user earpiece temperature, and environmental temperature that correlate to each other.
 7. The computer-implemented method of claim 1, further comprising determining, by the audio processing device, that the user earpiece is not located in a user ear, wherein the playing of the source audio signal and the recording of the recorded audio signal occur while the audio processing device has determined that the user earpiece is not located in the user ear, such that the determined temperature value is designated as an environmental temperature value.
 8. The computer-implemented method of claim 7 further comprising: determining, by the audio processing device and after the user earpiece has been determined to not be located in the user ear, that the user earpiece is now located in a user ear, and in response: (i) playing, with the audio processing device, a second source audio signal using the electroacoustic transducer, (ii) recording, with the audio processing device and while playing the second source audio signal, a second recorded audio signal, and (iii) determining, by the audio processing device, a second temperature value that is estimated to cause the second source audio signal that was played by the audio processing device to result in the second recorded audio signal, accounting for changes to the second source audio signal that occur due to application of one or more parameters, wherein the second temperature value differs from the determined temperature value that is designated as the environmental temperature value because temperature of the earpiece has changed after the earpiece was placed in the user ear; and estimating, by the audio processing device, a user body temperature value using the determined temperature value that is designated as the environmental temperature value and the second temperature value.
 9. The computer-implemented method of claim 8, wherein estimating the user body temperature using the determined temperature value and the second temperature value includes correlating the user body temperature to previously-calibrated sets of user body temperature, user earpiece temperature, and environmental temperature that correlate to each other.
 10. A computing system comprising: one or more processors; and one or more computer-readable media having instructions stored thereon that, when executed by the one or more processors, cause performance of operations playing, with an audio processing device, a source audio signal, including causing the source audio signal to be audibly output by an electroacoustic transducer of a user earpiece; recording, with the audio processing device and while playing the source audio signal, a recorded audio signal using the electroacoustic transducer of the user earpiece; identifying, by the audio processing device, one or more parameters that indicate how properties of the user earpiece affect playing of the source audio signal by the electroacoustic transducer, wherein at least one of the one or more parameters is temperature dependent; and determining, by the audio processing device, a temperature value that is estimated to cause the source audio signal that was played by the audio processing device to result in the recorded audio signal, accounting for changes to the source audio signal that occur due to application of the one or more parameters. 